More handpicked essays just for you.
Essay about the shared characteristics of mitochondria and chloroplast
Endosymbionts theory paper
Endosymbiosis summary paper
Don’t take our word for it - see why 10 million students trust us with their essay needs.
Mitochondria and chloroplasts have the likenesses with microscopic organisms that prompted the endosymbiont hypothesis. This hypothesis expresses that an early a castor of eukaryotic cell inundated an ocygen utilizing nonphotosynthetic prokaryotic cell. In the long run, the overwhelmed cell shaped an association with the host cell in which it was en shut, turning into an endosymbiont. Through the span of advancement the host cell and its endosymbiont converged into a solitary living being, an eukaryotic cell with a mitochondrion. As opposed to being limited by a solitary layer like organelles of the endomembrane framework, mitochondria and common chloroplasts have two layers encompassing them. Evidence the hereditary overwhelmed prokaryotes
I will get 5 test tubes and place them into the test tube rack. I will
For part one of the experiment, my team asked the question of which cell fraction of the measured pea seedlings will have a higher ratio of chloroplasts? My group tested for the activity of chloroplasts with three different pairs of cell fractions by two conditions of light and dark in three readings. The first two cell fractions, pellet one and two (P1, P2), are the hard sediments found at the bottom of a tube after it has been centrifuged (which are specimen, like the mitochondria and chloroplast, that are isolated from the rest) (Leicht and McAllister, 2016). The last cell fraction used was the supernatant two (S2), which is just the free liquid surrounding the pellet after the centrifuging of P2 (Leicht and McAllister, 2016). To test for this, DCIP (a chloroplast isolation buffer) was used to
Eukaryotic Cells are Deemed as a Result of the Evolution of Symbiotic Prokaryotes Both Prokaryotic and Eukaryotic cells over time have sustained very dynamic changes from one another. More specifically we have seen the appearance of a more complicated and organized cell structure, the nucleus. However the big question amongst scientists today is how did these changes first occur? A fundamental concept of this evolution is the belief in the natural progression 'from the simple, to the more complex.' However one popular theory that argues that Prokaryotic symbiosis was responsible for forming the Eukaryotic nucleus is the 'Endosymbiotic Theory' this theory was first proposed by a former Boston University Biologist known as Lynn Margulis in the 1960's.
ABSTRACT: Chloroplasts carry out photosynthetic processes to meet the metabolic demands of plant cells (Alberts, 2008). They consist of an inner thylakoid membrane and a stroma. (Parent et. al, 2008).In this experiment we demonstrate the unique protein compositions of isolated thylakoid and stromal fractions from broken and whole spinach chloroplasts. Because these compartments carry out different metabolic processes, we confirm our hypothesis that performing SDS-PAGE on these fractions will result in distinct patterns on the gels. In isolating and analyzing nucleic acid from broken, whole, and crude chloroplast samples we demonstrate that genes for photosynthetic protein psbA are found in chloroplast DNA, while genes for photosynthetic enzyme
Cellular respiration and photosynthesis are important in the cycle of energy to withstand life as we define it. Cellular respiration and photosynthesis have several stages in where the making of energy occurs, and have diverse relationships with organelles within the eukaryotic cell. These processes are central in how life has evolved.
The high rate of absorbance change in blue light in the chloroplast samples (Figure 1) can be attributed to its short wavelength that provides a high potential energy. A high rate of absorbance change is also observed in red light in the chloroplast samples (Figure 1), which can be accredited to the reaction centre’s preference for a wavelength of 680nm and 700nm – both of which fall within the red light range (Halliwell, 1984). Green light showed low rates of photosynthetic activity and difference in change in absorbance at 605nm in the chloroplast samples (Figure 1) as it is only weakly absorbed by pigments, and is mostly reflected. The percentage of absorption of blue or red light by plant leaves is about 90%, in comparison to the 70–80% absorbance in green light (Terashima et al, 2009). Yet despite the high absorbance and photosynthetic activity of blue light, hypocotyl elongation was suppressed and biomass production was induced (Johkan et al, 2012), which is caused by the absorption of blue light by the accessory pigments that do not transfer the absorbed energy efficiently to the chlorophyll, instead direction some of the energy to other pathways. On the other hand, all of the red light is absorbed by chlorophyll and used efficiently, thus inducing hypocotyl elongation and the expansion in leaf area (Johkan et al, 2012).
Hello everyone. Today for my speaking assignment, I will be speaking to you all about the mitochondrion because I don’t know what else to talk about. For the first part, I am just going to summarize what I know and won’t be going in depth with it as much. Anyways, as most people know, the mitochondrion is the powerhouse of the cell. Mitochondrion is singular while the plural version is mitochondria, which is the one people tend to say and it’s not wrong either way. It is an organelle found in most eukaryotic cells. In 1890, it was discovered by German pathologist Richard Altmann and was called “bioblast” at the time. People also were very skeptical at the time about his findings of the granules and even harshly criticized Altmann until the
The ribosomes are like the chefs of the restaurant because the chefs produce food for the patrons of the restaurant in the same way that the ribosomes link amino acids to form proteins in the cell. The Endoplasmic Reticulum is like the kitchen in the restaurant because the kitchen is where food is produced and cooked in the same way that the endoplasmic reticulum helps in the cell. The mitochondria/chloroplast is like the stove and oven in the restaurant because the stove and oven produced the energy for the food to cook and bake in the same way that the mitochondria supplies energy for the cell to use. The cytoplasm is like the dining room of the restaurant because the dining room allows the customers and other staff to move around and have space to sit in the same way that the cytoplasm allows molecules to move around the cell. The golgi apparatus is like the waiters of the restaurant because the waiters put in the order for a dish,receive it, and then carry it out from the kitchen to deliver to the customer in the same way that the golgi apparatus
In this lab we amplified a region of DNA that is found in the mitochondria. Mitochondria have their own set of DNA. Mitochondrial DNA has “16,500 DNA building blocks (base pairs), representing a small fraction of the total DNA in cells. — Mitochondrial DNA contains 37 genes,” (Genetics Home Reference, NIH, 2014) The part of the DNA that we amplified was the D-loop region. This part of the mitochondrial genome is the origin of replication for the mitochondria. This part of the mitochondria is also “prone to somatic mutation, which are a type of non-inherited mutation.” (Genetics Home Reference, NIH, 2014) One’s mitochondrial DNA is only inherited from the maternal side. The reason why is because when “an egg cell is fertilized, nuclear chromosomes from a sperm cell enter the egg and combine with the egg’s nuclear DNA producing a mixture of both parents’ genetic code.” (Groleau, PBS, 2014) Since the mtDNA is the exact same as the mother’s one can trace back the lineage of their maternal side and trace from what part of the world they are descended from. The mtDNA contains a history storybook of the travels and nomadic paths their ancestors took before their creation. The purpose of amplifying this region of mtDNA is to trace back our lineage.
Overview of Cellular Respiration and Photosynthesis Written by Cheril Tague South University Online Cellular Respiration and Photosynthesis are both cellular processes in which organisms use energy. However, photosynthesis converts the light obtained from the sun and turns it into a chemical energy of sugar and oxygen. Cellular respiration is a biochemical process in which the energy is obtained from chemical bonds from food. They both seem the same since they are essential to life, but they are very different processes and not all living things use both to survive ("Difference Between Photosynthesis and Cellular Respiration", 2017). In this paper I will go over the different processes for photosynthesis and the processes for cellular respiration and how they are like each other and how they are essential to our everyday life.
The start of any evolutionary story told about us lies within the origin of the eukaryote cell. This remarkable event consisted of a revolution of cell type matched in momentousness by the arrival on the biological scene of the prokaryote (O’Malley). Bacteria had a couple billion years head start on eukaryotes and have given rise to many biochemical processes that are essential to the ecosystem (Wernergreen). One organism living within another defines endosymbiosis. Nobody can say the exact origin of the eukaryote cell. The endosymbiosis theory dates back to the earliest 20th century and devotion to different models of its origins is strong and adamant (O’Malley).
In some way, shape, or form energy is one of the several reasons why there is an existence of life on earth. Cellular respiration and Photosynthesis form a cycle of that energy and matter to support the daily functions that allow organisms to live. Photosynthesis is often seen to be one of the most important life processes on Earth. Photosynthesis is a process by which plants use the energy of sunlight to convert carbon dioxide and water into glucose so other organisms can use it as food and energy. It changes light energy into chemical energy and releases oxygen. This way organisms can stay alive and have the energy to function. Chlorophyll is an organelle generally found in plants, it generates oxygen as a result too. As you can see without
The nucleus is one of the most important organelles in a eukaryotic cell. The shape of the nucleus is generally spherical, it should be oval, disc formed reckoning on the sort of cell. The nucleus was found by Robert Brown in 1831 while he was looking at orchids under a microscope. He discovered a blurred area in the cells of the flowers and called it the areola or the nucleus.
The mitochondria is an organelle which is generally an oval shape and is found inside the cytoplasm and is again apart of the eukaryotic cells. The main function of the mitochondria is to complete cellular respiration; in simple terms it acts like a digestive system to break down essential nutrients and to convert it into energy. This energy is usually found to in ATP which is a rich molecule taken from the energy stored in food. Furthermore, mitochondria stores calcium for signalling activities; such as heat, growth and death. They have two unique membranes and mitochondria isn’t found in human cells like the red blood cells yet liver and muscle cells are filled entirely with mitochondria.
Cells are the basic building blocks of all living things. The human body is composed of trillions of cells. They provide structure for the body, take in nutrients from food, convert those nutrients into energy, and carry out specialized functions. But it also contains highly organized physical structures which are called intracellular organelles. These organelles are important for cellular function. For instance Mitochondria is the one of most important organelle of the cell. Without Mitochondria more than 95% of the cell’s energy, which release from nutrients would cease immediately [Guyton et al. 2007].