En aquest experiment valorarem de forma quantitativa l'activitat enzimàtica de la Catalasa del fetge de pollastre. Dividirem la pràctica en dues parts. En la primera observarem la diferència d'activitat de la catalasa en diferents teixits animals i vegetals. Per aquesta part utilitzarem la pastanaga, la patata, el tomàquet i el fetge i el cor de pollastre. En la segona part veurem la influència de determinats factors en l'activitat enzimàtica...
La catalasa és un enzim present en els peroxisomes de les cèl·lules animals i vegetals que s'encarrega d'eliminar l'aigua oxigenada que es forma en algunes reaccions del metabolisme. La reacció química és la següent.
H2O2 --> 1/2 H2O + O2
Material:
Teixits animals; fetge i cor de pollastre
Teixits vegetals: patata, pastanaga, tomàquet
Tub d'assaig de coll ampla
Vas precipitats
Termòmetre
Gradeta
Aigua destil·lada
Aigua oxigenada al 3%
Pinces
Bisturí
Tisores
Protocol:
Experiment 1: Quin teixit presenta més activitat de la catalasa?
1- Tallarem tres trossos de patata, tomàquet, i pastanaga que pesin més o menys el mateix (mateixa mida 1cm3)
2- També tallarem dos trossos, un de fetge i un de cor de la mateixa mida i pes (1,2 g la patata, 0,9 g tomàquet, 1,1 g pastanaga, 0,9 g fetge i 1,2 g cor.) .
3- Ho posarem en cinc tubs amb cada teixit en un tub + 5 ml d'aigua destil·lada en cada.
4- Després posarem 2 ml d'aigua oxigenada i marcarem l'alçada que assoleixen les bombolles en cada tub. Mesurarem aquesta alçada en mm.
(imatge agafada de http://pbsciencelab.blogspot.com.es/)
Preguntes:
Variable dependent i independent?
Alçada de bombolles és la variable dependent i els diferents teixits la independent.
Problema que es vol investigar?
Quin teixit presenta més activitat de la catalasa?
Explicació dels resultats:
Hem pogut veure que el cor és el teixit que més activitat enzimàtica. Els teixits animals, comparat amb els teixits vegetals presenta més activitat.
Experiment 2: Com afecten diferents factors en l'activitat de la catalasa?
Agafarem el teixit del fetge i el posarem en 5 tubs d'assaig sota condicions diferents
1er tub: tros de teixit a temperatura ambient (a 19 graus 1 g)
2n tub: tros de fetge amb 10 ml d'HCl al 10% (0,9 g)
3er tub: fetge congelat (a 2 graus 1,2 g)
4t tub: fetge bullit. (1g)
5è tub: fetge submergit en una dissolucio saturada de NaCl (0,8 g)
Afegirem 2 ml d'aigua oxigenada i anotarem l'alçada de les bombolles (controlarem el temps que seran 10 minuts, el pes i la quantitat de dissolució.
PREGUNTES
Variable dependent i independent?
La variable dependent és l'alçada de les bombolles i la independent les diferents condicions a les que hem sotmés el fetge.
Problema que es vol investigar?
Com afecten diferents condicions d'un teixit animal (fetge) en l'activitat de la catalasa sobre aquest?
Explicació dels resultats:
Hem pogut observar que el tub amb més activitat de la catalasa ha sigut el de NaCl, seguidament el congelat (perquè s'estava descongelant) i després el de temperatura ambient. Els dos que han presentat menys activitat han sigut amb àcid clorhídric i el bullit perquè estaven fora del pH òptim i de la Tª òptima.
Quina és la funció de la catalasa en els teixits animals i vegetals? On es troba aquest enzim?
És un enzim que es troba als peroxisomas de les cèl·lules eucariotes. La funció de la catalasa és descomposar l'aigua oxigenada en aigua i oxigen ja que en el metabolisme es produeix aquesta aigua oxigenada que és una molècula tòxica.
Per què quan ens fem una ferida ens posem aigua oxigenada?
L'existència de catalasa en els teixits animals, s'aprofita per utilitzar l'aigua oxigenada com a desinfectant quan es tira sobre una ferida. Com molts dels bacteris patògens són anaerobis (no poden viure amb oxigen), moren amb el despreniment d'oxigen que es produeix quan la catalasa dels teixits actua sobre l'aigua oxigenada.
miércoles, 21 de octubre de 2015
sábado, 30 de mayo de 2015
L.21 Mitosis in an onion root
On Monday 18th of May we did an experiment about the observation of mythosis. Mitosis is the process in which a eukaryotic cell nucleus splits in two, followed by division of the parent cell into two daughter cells. So the objective of this experiment is to view the different stages of a mitosis in the microscope.
MATERIALS
-Onion
-Orceine A and B
-Dropper
-Watch glass
-Beaker
-Forceps
-Bunsen burner
-Lighter
PROCEDURE
1- A week ago we left an onion in a beaker with some water, (only the tip of the onion touched it) so its roots will grow so we can see the process of mitosis.
2- To start our experiment we took the onion and cut the tip of a root and put it in the watch glass.
3- Then with the dropper we took the orceine A and put some drops on the root and we took the watch glass with the wooden forceps and put it on the bunsen burner so the orceine and the root would heat. Some fumes began to evaporate. We had to be careful to not to burn the root so the watch glass could not be too hot, we should be able to touch it with our hand!!
4- After that we took the root with the forceps and put it on a slide and added a couple of drops of orceine B, we waited a couple of minutes.
5- Then with the scalpel we cut 3mm leaving the tip, and always knowing where the tip is.
6- Finally we added a coverslip and used the squash method so we could observe the cells on the microscope.
Results and observations: Unfortunately, my group was able to only see the prophase so we asked our classmates if they found anything and they had more luck.
MATERIALS
-Onion
-Orceine A and B
-Dropper
-Watch glass
-Beaker
-Forceps
-Bunsen burner
-Lighter
PROCEDURE
1- A week ago we left an onion in a beaker with some water, (only the tip of the onion touched it) so its roots will grow so we can see the process of mitosis.
2- To start our experiment we took the onion and cut the tip of a root and put it in the watch glass.
3- Then with the dropper we took the orceine A and put some drops on the root and we took the watch glass with the wooden forceps and put it on the bunsen burner so the orceine and the root would heat. Some fumes began to evaporate. We had to be careful to not to burn the root so the watch glass could not be too hot, we should be able to touch it with our hand!!
4- After that we took the root with the forceps and put it on a slide and added a couple of drops of orceine B, we waited a couple of minutes.
5- Then with the scalpel we cut 3mm leaving the tip, and always knowing where the tip is.
6- Finally we added a coverslip and used the squash method so we could observe the cells on the microscope.
Results and observations: Unfortunately, my group was able to only see the prophase so we asked our classmates if they found anything and they had more luck.
L.20 The chloroplast and the photosynthesis
This Monday 11th of May we did an experiment with an algae. During the photosynthesis, plants and algae produce oxygen. The reasearch aspect of this science lab project is to assess how light intensity affects the rate at which photosynthesis occurs and the rate of oxygen production. This experiment is done to relate the light intensity with the photosynthesis process, to measure the rate of photosynthesis and to identify the products of the process and the variables that can affect it.
MATERIALS
-Algae
-600 ml beaker
-Test tube
-Funnel
-Tap water
-Light source
-Ruler
PROCEDURE
1- First we assigned the different distances to do the experiment and compare the results to each group.
2- We took the 600 ml beaker and placed 7 g of an algae under a clear funnel inside the beaker (the wide end goes over the algae like in the image). The funnel was raised off the bottom on pieces of blue-tack to allow unhampered diffusion of CO2 to Elodea.
3-We didn't have sodium bicarbonate so we filled the beaker with tap water, the algae and the funnel should be completely under the water.
4- Then we filled a test tube with tap water and placed the thumb over the end of the test tube. We turned the test tube upside down taking care that no air enters and no water comes out and we put this test tube over the end of the funnel (the skinny part)
5- We marked the level of the water on the surface of the test tube with a marker pen.
6- Each group placed the preapartion close to a light source, each group placed the preparation in a different distance 5, 10, 20 and 25 cm, and one with no light source.
7- We also measured the temperature.
8- Finally we left this preparation for and hour and a half. After this time we measured the difference of gas accumulation on the top of the test tube.
Results and observations: everything will be explained in the questions below:
QUESTIONS
1- Identify the dependent and the independent variable of this experiment.
Dependent: gas production, Independent: distance (intensity of the light)
2-Using the data from your results prepare a graph and describe what happened to the amount of gas in the test tube.
My group had the 10 cm distance and our water level decreased about 0,4 mm in an hour and a half.
If you have more light intensity, the phtoshyntethic rate will be higher. We controled the temperature and the algae quantity because this could have and influence on the result. Also, we think that Laura's and Andrea's result is incorrect because the distance is higher so the water level decrease should be lower than the other. Maybe they measured it incorrectly.
3-How much gas was producted in the test tube after one hour? And an hour and a half?
We put the results in the graph.
4-Write the photosynthesis equation. Explain each part of the equation. Which subtances are produced by photosynthesis. Which gas is produced that we need in order to live? Plants take in carbon dioxide by diffusion through their stomata. Light energy enters the plant via leaves and water and nutrients enter through roots. The plant is then able to make glucose and oxygen. The glucose moves from the leaves to the plant and the oxygen diffuses out of the leaves. The gas that we need in order to live is oxygen.
In the process of photosynthesis, phytoplankton release oxygen into the water. Half of the world's oxygen is produced via phytoplankton photosynthesis. The other half is produced via photosynthesis on land by trees, shrubs, grasses, and other plants.
MATERIALS
-Algae
-600 ml beaker
-Test tube
-Funnel
-Tap water
-Light source
-Ruler
PROCEDURE
1- First we assigned the different distances to do the experiment and compare the results to each group.
2- We took the 600 ml beaker and placed 7 g of an algae under a clear funnel inside the beaker (the wide end goes over the algae like in the image). The funnel was raised off the bottom on pieces of blue-tack to allow unhampered diffusion of CO2 to Elodea.
3-We didn't have sodium bicarbonate so we filled the beaker with tap water, the algae and the funnel should be completely under the water.
4- Then we filled a test tube with tap water and placed the thumb over the end of the test tube. We turned the test tube upside down taking care that no air enters and no water comes out and we put this test tube over the end of the funnel (the skinny part)
5- We marked the level of the water on the surface of the test tube with a marker pen.
6- Each group placed the preapartion close to a light source, each group placed the preparation in a different distance 5, 10, 20 and 25 cm, and one with no light source.
7- We also measured the temperature.
8- Finally we left this preparation for and hour and a half. After this time we measured the difference of gas accumulation on the top of the test tube.
Results and observations: everything will be explained in the questions below:
QUESTIONS
1- Identify the dependent and the independent variable of this experiment.
Dependent: gas production, Independent: distance (intensity of the light)
2-Using the data from your results prepare a graph and describe what happened to the amount of gas in the test tube.
My group had the 10 cm distance and our water level decreased about 0,4 mm in an hour and a half.
If you have more light intensity, the phtoshyntethic rate will be higher. We controled the temperature and the algae quantity because this could have and influence on the result. Also, we think that Laura's and Andrea's result is incorrect because the distance is higher so the water level decrease should be lower than the other. Maybe they measured it incorrectly.
3-How much gas was producted in the test tube after one hour? And an hour and a half?
We put the results in the graph.
4-Write the photosynthesis equation. Explain each part of the equation. Which subtances are produced by photosynthesis. Which gas is produced that we need in order to live? Plants take in carbon dioxide by diffusion through their stomata. Light energy enters the plant via leaves and water and nutrients enter through roots. The plant is then able to make glucose and oxygen. The glucose moves from the leaves to the plant and the oxygen diffuses out of the leaves. The gas that we need in order to live is oxygen.
INVESTIGATION
-Which is the origin of the oxygen that we breathe?
The trees and plants that are around us and other organisms that do the photosynthesis.
-Where are the lungs of our planet?
Phytoplankton need two things for photosynthesis and thus their
survival: energy from the sun and nutrients from the water.
Phytoplankton absorb both across their cell walls.
In the process of photosynthesis, phytoplankton release oxygen into the water. Half of the world's oxygen is produced via phytoplankton photosynthesis. The other half is produced via photosynthesis on land by trees, shrubs, grasses, and other plants.
domingo, 22 de marzo de 2015
viernes, 20 de marzo de 2015
L.18 Life in a drop of water
We observed pond water and we found an eucariotic unicelular organism with two flagels.
domingo, 8 de marzo de 2015
L17. Gram staining
MATERIALS
-Hot plate
-1 slide
-1 coverslip
-Tongs
-Needle
-Gram stain (crystal violet, iodine and safranin)
-Ethanol
-Microscope
-Yogurt
PROCEDURE
1- First we prepared a heat fixed sample of the bacteria by spreading somre yogurt on a slide and drying it on the hot plate.
2-Then we covered the smear with crystal violet and waited for 1 min. After that we rinsed it with distilled water.
3-We applied iodine solution for another 1 min and again rinsed it with distilled water.
4-Then we decolorized using ethaol. Drop by drop until the purple stops flowing and washed immediately with distilled water.
5-Lastly we covered the sample with safranin stain for and exposure time of 45 seconds and rinsed the sample with tap water.
6-Finally we dried the under part of the slide with paper and viewed it on the microscope.
Results and observations: We saw some bacteria red and other purple. Why?
Gram Positive Cell Wall:
Gram-positive bacteria have a thick
cell wall which is made up of peptidoglycan (50-90% of cell
wall), which stains purple. Peptidoglycan is mainly a polysaccharide
composed of two subunits. The thick
peptidoglycan layer of Gram-positive organisms allows these organisms to
retain the crystal violet-iodine complex and stains the cells as
purple.
Gram Negative Cell Wall:
Gram-negative bacteria have a thinner
layer of peptidoglycan (10% of the cell wall) and lose the crystal
violet-iodine complex during decolorization with the alcohol rinse, but
retain the counter stain Safranin, thus appearing reddish or pink. They
also have an additional outer membrane which contains lipids, which is
separated from the cell wall by means of periplasmic space.
L16. Epidermis cells
On Monday 2nd of March we did two experiments using the microscope, and now i'm going to explain the first one. The objective of this experiment was to identify the shape of epidermis cells, and to identify and explore the part of the stoma and see how it changes its shape when we add salt water.The pores open to facilitate uptake of carbon dioxide
and close to limit the loss of water
MATERIALS
-Slide
-Cover slip
-Tap water
-10% salt water
-Forceps
-Dropeper -Scissors
-Needle
-Leek
PROCEDURE
1-First we cut the stalk of the leek and pulled out the transparent part of the epidermis using forceps.
2-Then we placed the peel into the slide containing a drop of tap water (so the cells don't die) .
3-Next we took a cover slip and placed it gently on the peel with the aid of a needle.
4-We viewed it in the microscope and took pictures of it.
5-Then we prepared a 10% salt solution and put the solution with a dropper on the left part of the slide (so it touched the cover slip) and placed a piece of cellulose paper in the opposite side of the cover slip to let the dissolution go through the sample.
6-Finally we looked through the microscope once more and took more pictures.
Results and observations:
When we first saw the cell we noticed the characteristic shape of a plant cell, a geometric one, a squareand the cell wall. Then we looked closer at it and saw the stomas: they were open. Stoma opens when the guard cells are turgid, when the water potential of the cells adjacent to the guard cells are higher than that in the cell sap of the guard cells and the water molecules from the adjacent cells move into the guard cells by osmosis. The opening of the stoma is an advantage because it allows gaseous exchange to take place.
Then we added salt water and took a second look. Now the stomas were closed because the adjacent cells were hypertonic and the guard cells hypotonic so the water molecules moved out of the guard cells into the adjacent cells by osmosis. When this happens, the guard cells become plasmolysed which in turn causes the stoma to close.
QUESTIONS
1- What is the major function of a cell membrane?
The membrane is selectively permeable to ions and organic molecules and controls the movement of substances in and out of cells. Also it protects the cell from its surroundings.
2- What is the major function of the cell wall?
It surrounds the cell membrane and provides structural support and protection to it. Also it acts as a filtering mechanism and as a pressure vessel, preventing over-expansion when water enters the cell.
3-How does salt affect the cells shapes? And the stomes?
I explained it earlier.
MATERIALS
-Slide
-Cover slip
-Tap water
-10% salt water
-Forceps
-Dropeper -Scissors
-Needle
-Leek
PROCEDURE
1-First we cut the stalk of the leek and pulled out the transparent part of the epidermis using forceps.
2-Then we placed the peel into the slide containing a drop of tap water (so the cells don't die) .
3-Next we took a cover slip and placed it gently on the peel with the aid of a needle.
4-We viewed it in the microscope and took pictures of it.
5-Then we prepared a 10% salt solution and put the solution with a dropper on the left part of the slide (so it touched the cover slip) and placed a piece of cellulose paper in the opposite side of the cover slip to let the dissolution go through the sample.
6-Finally we looked through the microscope once more and took more pictures.
Results and observations:
When we first saw the cell we noticed the characteristic shape of a plant cell, a geometric one, a squareand the cell wall. Then we looked closer at it and saw the stomas: they were open. Stoma opens when the guard cells are turgid, when the water potential of the cells adjacent to the guard cells are higher than that in the cell sap of the guard cells and the water molecules from the adjacent cells move into the guard cells by osmosis. The opening of the stoma is an advantage because it allows gaseous exchange to take place.
Then we added salt water and took a second look. Now the stomas were closed because the adjacent cells were hypertonic and the guard cells hypotonic so the water molecules moved out of the guard cells into the adjacent cells by osmosis. When this happens, the guard cells become plasmolysed which in turn causes the stoma to close.
QUESTIONS
1- What is the major function of a cell membrane?
The membrane is selectively permeable to ions and organic molecules and controls the movement of substances in and out of cells. Also it protects the cell from its surroundings.
2- What is the major function of the cell wall?
It surrounds the cell membrane and provides structural support and protection to it. Also it acts as a filtering mechanism and as a pressure vessel, preventing over-expansion when water enters the cell.
3-How does salt affect the cells shapes? And the stomes?
I explained it earlier.
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