Grasshopper Disection

Grasshopper Dissection 

-Grasshoppers are found on all continents on Earth except for Antarctica. They mostly prefer to live in open, dry environments that contain plenty of grasses and other low plants. However, some species like to live in jungles or forests.

-Grasshoppers eat plants- they are primarily herbivores. Their nutrition mostly consists of leaves but sometimes consists of stems, seeds, and flowers. Although they are herbivores, they sometimes eat dead insects for protein.

-Since grasshoppers do not have lungs, they breathe through spiracles, or tiny holes in their bodies. They contain 10 pairs of spiracles on their abdomens and thoraxes. Air moves into the front spiracles and leaves through the back spiracles.

-The ancestors of grasshoppers existed long before dinosaurs existed. They evolved more than 200 million years ago. Primitive grasshoppers are found in fossils that are remains from the Carboniferous period, 300 million years ago.

Sources-

http://www.biokids.umich.edu/critters/Acrididae/

http://animals.howstuffworks.com/insects/grasshopper-info1.htm

http://insects.about.com/od/grasshoppersandcrickets/a/10-Cool-Facts-About-Grasshoppers.htm

Dissection

Major internal/external anatomy-

 

tibia- lower part of the leg for movement

 

femur- higher part of the leg for movement

 

forewing- protects the hind wings and used for flight

 

prothorax- protects the digestive tract and blood vessles

 

antenna- used as sensory feelers for touch, taste, and equilibrium

Major internal/external anatomy-

crop- food storage

gastric ceca- secretes enzymes into the stomach

stomach- breaks down food; it’s the first site of chemical digestion

large intestine- collects waste and absorbs water

small intestine- absorbs nutrients from food

Anatomy Sources-

 

http://www.hamilton-local.k12.oh.us/Downloads/5-10_Grasshopper%20Dissection.pdf

http://iws.collin.edu/efelker/Biology%201407%201409/grasshopper%20dissection.pdf

https://quizlet.com/11174119/grasshopper-dissection-flash-cards/ ]http://www.biologyjunction.com/grasshopper_dissection.htm

 

Crayfish Dissection

Crayfish Dissection 

-Crayfish live in almost all bodies of freshwater. They can survive in ponds, lakes, streams, rivers, and sometimes even water-filled ditches.

-They get their nutrition from both animals and plants, making them omnivorous. They eat both living and dead organisms, as long as they are relatively fresh. Some food they eat includes worms, insect larvae, frogs, salamanders, toads, insects, and fish eggs.

-Crayfish breathe through their gills which are located on both sides of their cephalothorax. Their gills are protected under their exoskeletons. Once passed through their gills, oxygen passes and diffuses into their bloodstream. Carbon dioxide leaves through the gills and is passed into the water.

-Red colored crayfish are the most common, followed by blue colored crayfish, and least commonly white crayfish.

Sources-

http://www.fcps.edu/islandcreekes/ecology/crayfish_%28cambarus%29.htm

http://www.ehow.com/info_10016579_crayfish-oxygen.html

http://www.johnston.k12.ia.us/schools/lawson/gradelevellinks/crayfish/funfact.html

Dissection

Major internal/external anatomy-

 

third maxilliped- used to manipulate food

 

walking legs- used for movement and is attached to gills

 

swimmerets- used for movement and determining sex

 

 

Major internal/external anatomy-

 

telson/uropod- used in rapid, backwards escape swimming

 

abdomen- segmented and flexible for easy movement

 

thorax- makes up the cephalothorax

 

cervical groove- separates the head and thoracic regions

 

head- makes up the cephalothorax

 

cephalothorax- used as an armor/ protection

 

compound eye- allows the crayfish to see and detect movement

 

cheliped- claws to grab onto things and defense against predators

 

antenna- used as sensory feelers for touch, taste, and equilibrium

 

 

Major internal/external anatomy-

 

stomach- breaks down food; it’s the first site of chemical digestion

 

gills- water and oxygen exchange

 

heart- pumps blood throughout the crayfish’s body

 

Major internal/external anatomy-

intestine- the small intestine absorbs nutrients from food and the large intestine collects waste and absorbs water

 

tail muscles- help in strong movement of the crayfish

Anatomy Sources-

http://mrescience.com/images/pdf/pdf_life/crayfish_dissection.pdf

http://biologycorner.com/worksheets/crayfishexternal.html

PGLO Transformation Lab

Purpose

     In this experiment, we were observing bacterial growth and transforming the bacteria. The process allowed us to further understand how transformation occurs, what happens biologically to the bacteria when genes are moved, and the significance this process has on life in both prokaryotic and eukaryotic cells.

Intro

     Transformation is a process used in prokaryotic as well as eukaryotic life cycles to genetically modify a cell by introducing  separate DNA into the cell with the help of a plasmid. Plasmids are genetic structures in a cell that are often used in laboratories to manipulate genes. They are small, circular DNA molecules in the cytoplasm of cells that carry supplementary genes and replicate independently of the chromosome. They can even lead a cell to being antibiotic resistant. The pGLO plasmid contains genes for green florescence (GFP) as well as a gene that has resistance to the antibiotic ampicillin. Scientists such as biochemists sometimes use a method called heat shock which is where cells are put into a higher than ideal temperature of the organism. This method opens up pores in the plasma membrane due to the sudden increase in temperature, allowing plasmids to enter the bacterial cell.

Methods

Because this lab involved E.coli and making it antibiotic resistant, extra precautions, sterile equipment, and good lab techniques were used while doing this lab. No one was harmed during this genetic transformation.

Micro test tubes were labeled +pGLO and -pGLO and transformation solution was added into each tube.

Using sterile loops, we picked up the E. Coli and placed them into both test tubes.

All the while both test tubes were immersed in a cup of ice in order to keep them cold. Then we grabbed another sterile loop and obtained pGLO plasmid DNA where we only placed into the +pGLO and not the -pGLO. After ten minutes sitting in the cup of ice, we heat shocked the test tubes. This meant putting both tubes into a 42 degree Celsius water bath for 50 seconds then placing it back into the ice immediately afterwards. Next, LB nutrient broth was placed into both test tubes. Finally, we placed the +pGLO into the LB/amp and LB/amp/ara transformation plates, the -pGLO was placed into the LB/amp and LB control plates, and gently spread the the liquid across the plate. The only thing left to do was to put them into the incubator and wait.

Our lab group was stunned by our results. The following pictures are what we saw the next day under UV lighting:

The glowing E. Coli under ultraviolet light. We have a large culture here, effectively telling us that the lab was an overall success.

A different culture with even better growth than the previous one. This culture happens to include the E. Coli that were antibiotic resistant to the Ampicillin

E. Coli alone in nutrient broth

E. Coli in nutrient broth with ampicillin. We cannot expect quality growth in this culture from bacteria without the inserted plasmid to make them resistant to ampicillin.

Data

Here is our math to determine how well the bacteria altered its genome to incorporate the new pGlo plasmid

Discussion

Our E. Coli pGLO transformation lab had the best results out of any lab we have done this school year. Plentiful colonies of E. Coli were produced on the control LB plate for both the wild-type and recombinant pGLO E. Coli. In terms of recombination efficiency, it was a complete success: we had one of the highest efficiencies of any lab group. Recombinant E. Coli flourished on the LB plate with ampicillin and fluoresced on the LB plate with ampicillin and arabinose as expected:

 The wild-type E. Coli, as expected, did not grow on any LB plate with ampicillin. Even on these empty plates, there was very little contamination. 

We contribute our success to our meticulous following of lab procedures. We used the correct amounts of materials and were not lax when it came to correct timing for the heat shock. The transfer from cold to hot to cold was immediate and precise. Our results confirmed our hypothesis perfectly: naturally, the antibiotic resistant E. Coli would grow in an ampicillin rich environment, while the wild-type would not. Overall, we are very pleased with our results.   

Conclusion

By shining ultraviolet light on the petri dish and seeing E. Coli glow in the dark, we had visual proof that the plasmid had been successfully incorporated into the bacteria cells. In addition to this, only bacteria with the inserted plasmid could grow on the ampicillin culture, which also tells us that this population of E. Coli is resistant antibiotics. This lab is designed to show how genetic engineering works and the fascinating results following the simple insertion of just one new gene to the bacteria's genome. This practice is something scientists are studying on a much larger scale with the hope that humans may find additional benefits from using restriction enzymes to alter the human genome.

References

http://www.cliffsnotes.com/sciences/biology/microbiology/microbial-genetics/the-bacterial-chromosome-and-plasmid

en.wikipedia.org/wiki/Heat_shock

http://www.jove.com/science-education/5059/bacterial-transformation-the-heat-shock-method

Restriction Mapping Lab

Purpose

     In this experiment, we separated DNA fragments by the size of their base pairs and analyzed the digested sites where restriction enzymes cut. This helped determine the number of cut sites for each restriction enzyme and their positions next to each other. We determined the total size of the DNA strands by adding up the sizes of the fragments from each digest. Since we knew that smaller DNA fragments migrate quicker than the larger ones, we were able to use the data for gene mapping.

Intro

     Molecular biology techniques often include the use of restriction enzymes to digest DNA as well as the separation of DNA fragments with the help of agarose gel electrophoresis. These techniques can be used for gene mapping and even for studying human genetic diseases. Restriction enzymes are enzymes that have the property to catalyze the cleavage of certain DNA molecules at specific base sequences. They are used for chromosomal mapping and also for gene splicing in recombinant DNA technology. Gel electrophoresis is a method used in labs to separate DNA, RNA, and proteins by their molecular size. In the process, the molecules are separated by being pressed through a gel (often agarose gel) by an electrical field. A negative charge is applied so that the molecules move towards the positive charge to be analyzed. 

Methods

The first thing that we did was use a needle point pipet in order to load the DNA into the gels, the first column contained the pMAP or lambda (“clear”) which will act as a marker within our results. Skipping the second, the third column contained PstI (“blue”), the fourth PstI/SspI (“red”), the fifth PstI/HpaI (“white”), and the sixth column with all three PstI/SspI/HpaI (“yellow”).

A picture of our group's gel; GO GO GO!

After placing the DNA into the wells (which was actually harder than it looks… at least for our lab group…), we closed the top of the electrophoresis chamber and turned on the voltage. As a result, the DNA should move from one end to the other positive side of the electrophoresis apparatus.

When we came back the next day, the gels were stained in order to make it easier to see the marks on the gel.

Graphs and Charts

Our picture of a plasmid with the restriction enzymes in their approximate location. 

Discussion

Although our results were not the best because our group had trouble placing the DNA into the gel, we were still able to draw data from the results of other lab groups. With the help of the marker lane on the far left of the gel, we were able to approximate the distance between the different restriction enzymes within a plasmid. The PstI well should only have one marker, the middle should have two and the farthest right should have three markers. By using this approximation, the distance of the strands should have been a total of 3900 and each column should have that total.  

Conclusion
The results from the gel tell us the approximate length of each band, which allowed us to visualize and the draw a full plasmid, annotated with the locations of each band along the ring-like structure. This lab is unique because we see how biology comes into play with forensic science. Comparing the band patterns of a suspect and victim creates a very powerful convition case if there is a clear match. Gels are simple to use, easy to understand and remarkably accurate, so it's no wonder that this concept has appeared on the AP Biology test for 15 consecutive years.

References
https://barnard.edu/sites/default/files/inline/restriction_enzyme_digestion_lab.pdf

http://www.nature.com/scitable/definition/gel-electrophoresis-286

How to Extract DNA from Strawberries

Here is a little How-to list of how to extract DNA from strawberries. You will need a test tube, a plastic bag, a coffee filter paper, a pipette, DNA extraction buffer and icy cold isopropyl alcohol.

1. First, grab a strawberry and place it inside a plastic bag. Squish the strawberry to a pulp

2. Then fill a test tube a quarter full with DNA extraction buffer (soapy salty water) and pour it's contents into the plastic bag

3. Mix the buffer and smashed strawberries 

4. Grab another test tube and place a coffee filter paper at the top of the tube.

5. Strain the strawberry through the the coffee filter paper so that the liquid drips to the bottom of the test tube

6. When enough liquid has reached the bottom of the test tube, throw away the coffee filter paper and the strawberries.

7. With you test tube with the strawberry liquid, fill it with some ice cold isopropyl alcohol by pipetting it down the side of the tube 

8. Wait a couple minutes and you should begin to see the DNA begin to form

9. Use something to pull the DNA out of the the bottom of the test tube and witness this amazing phenomenon! 

Mitosis & Meiosis Lab

Exercise 3A: Cell Replication

Purpose

In this lab, we were investigating the process of mitosis by looking at slides of onion root tip. We were looking at the slides in order to see the products as well as the relative duration of the different phases throughout mitosis. By viewing the onion root tip cells, we were able to identify the different stages of mitosis in plant cells.

Introduction

In eukaryotes, mitosis is the process in which cell division results in two daughter cells with identical sets of chromosomes. The first and longest stage of mitosis is known as prophase, in which chromosomes become visible and centrioles separate in order to move to opposite poles of a cell. The second stage is called metaphase and this is where the chromosomes line up in the middle of the cell and connect to the spindle fibers at their centromere. The third step is anaphase, where the sister chromatids separate into individual chromosomes and they pull apart from each other. The fourth step is telophase and this is the last stage where the chromosomes all gather at opposite sides of the cell and they lose their rod like shapes. New nuclear membranes form around each DNA and the spindle fibers disappear. Cytokinesis occurs after the fourth step and the cell membrane pinches so that the cell finally divides into two.

Methods

The above picture illustrates a root cell during Interphase, or, the time during which the cell is not dividing. While the nucleus of the cell is visible (the red dot in the center). There is no chromatin evident under the lens of the microscope.

Now the cell enters the first phase of Mitosis, better known as Prophase. During Prophase, the cell begins to condense its chromosomes in preparation for division. If you look closely above, you may see small dots within the nucleus. The chromosomes are now visible simply because they are so concentrated within the nucleus of the cell.

This picture shows the cell in Metaphase, which is identiifed by the chromosomes lining up along the center of the cell.

In this picture, we see two nuclei and a cell plate, which means the cell is in Telophase. Once the cleavage has formed, cytokinesis will officially divide the cell into two identical daughter cells.

Data

This table shows the amount of each phase within each field. The time in each stage was found by multiplying the percent of total cells counted x 1,440 minutes. Interphase had the longest time and Anaphase had the least.

Graphs and Charts 

This is a pie chart of the onion root tip cell cycle and the data was provided by the table above!

Discussion

Conclusion

This lab served as an effective means to show real cells in each stage of mitosis. While it is good to describe each stage of the cell cycle, being able to recognize what process a cell is undergoing in real life is still a valuable skill. Aside from allowing us to see plant cells up and close, this is a powerful tool for reviewing Mitosis.

References 

http://www.cellsalive.com/mitosis.htm

http://www.marietta.edu/~biol/introlab/Onion%20root%20mitosis.pdf

Exercise 3B: Meiosis

Purpose

In this experiment, we were simulating the stages that occur in meiosis, a type of cell division in sexually reproducing eukaryotes, with the use of chromosome models. With the use of these models, we were able to look at crossing over, when homologous chromosomes exchange parts, as well as the recombination that occurs in the process of meiosis. 

Introduction 

Meiosis is the shuffling process of genes that occurs when organisms such as plants, animals, and sometimes fungi are ready to reproduce. Meiosis begins in prophase I; meiosis is when two diploid cells divide and then divide again resulting in four haploid cells. Genetic variation through meiosis occurs when maternal and paternal chromosomes cross over and exchange their segments. In metaphase I, the tetrads line up and in anaphase I the pairs of homologous chromosomes split up. 

The summarized steps of Meiosis

Methods/Discussion 

These beads illsutrate the appearance of chromatin during Interphase, when the cell is not dividing.

In Prophase I, the chromatin begins to condense and prepare for cellular division

Now the chromosomes break in certain sections, and swap genetic information with other chromosomes in order to acheive variability. This process is known as "Crossing Over"

The final result of "Crossing Over" One red bean and one yellow bead are exchanged to make the gametes different from their parents.

The area where Crossing Over ocurred is where the chromosomes will line up along the center of the cell.

Now the Sister Chromosomes separate, with one chromosome going to one side of the cell and part of it moving with the other chromosome to the other side of the cell.

The chromosomes then move to opposite ends of the cell and a nuclear envelope begins to form to separate the two chromosomes. Two haploid cells are thus formed and then the organism moves onto Interphase II (AKA interkinesis). 

These next pictures show what happens during Meiosis II where the chromosomes are slip in order to produce two more daughter cells. In this phase (Prophase II) centrioles move to the opposite sides of the cell.

The chromosomes then move to the middle of each of their own cell.

The centromeres and chromatids separate and move to the opposite sides of the cell.  

Finally the chromosomes are all separated and begin to form their own nuclear envelopes. The result is four daughter cells.

Data

This table shows the similarities and differences of mitosis and meiosis.

Discussion

Conclusion

The use of beads in this lab provides an effective way to view chromosomes conceptually. By using two colors (red and yellow) we are able to distinguish one chromosome from another and see how the process of crossing over occurrs and how this leads to genetic variability among gametes. We can look at a cell to understand Meiosis, but we cannot know how the cell undergoes this process without focusing on the chromosomes within.

References

http://www.marietta.edu/~biol/introlab/Onion%20root%20mitosis.pdf

http://www.biology4kids.com/files/cell2_meiosis.html