1. By Ellie Masserrat Pian Lu John Taucher USING BACTERIA MORPHOLOGY CHARACTERISTICS TO STUDY BACTERIAL DIVERSITY. 092404 EMJT

2. Bacteria…? n Bacteria are often viewed as the cause of diseases in humans and animals. n Some bacteria are useful, for example certain bacteria aids in digestion. n Bacteria make up the base of the food web in many environments. n Bacteria are of such immense importance because of their extreme flexibility, capacity for rapid growth and reproduction, and great age. n They can be photosynthetic, using light, or chemosynthetic, using inorganic chemicals as the source of energy, but most are heterotrophic, absorbing nutrients from the environment. Leptospira, causes serious disease in livestock

3. Background Information Prokaryotes n Prokaryotes represent two domains, bacteria and archaea. n Archaea live in Earth’s extreme environments. n Bacteria are the most abundant and diversified organisms on Earth.

4. Bacterial Structure n Biochemical processes that normally occur in a chloroplast or mitochondrian of eukaryotes will take place in the inner membrane of prokaryotes. n Bacterial DNA is circular and arrayed in a region of the cell known as the nucleotide. n Scattered within bacteria’s inner membrane are numerous small loops of DNA known as plasmids.

5. Structure n Some bacteria have flagella with a different microtubule structure than the flagella of eukaryotes.. n Ribosomes are the structures in cells where proteins are assembled. n Bacterial ribosomes have different sized ribosomal subunits than do eukaryotes.

6. Bacteria Have One of Three Cellular Shapes n Rods (bacilli) n Coccoid-Shaped n Spirilla

7. Reproduction n Prokaryotic cell division is binary fission. – Single DNA molecule that first replicates. – Attaches each copy to a different part of the cell membrane. – Cell begins to pull apart. – Following cytokinesis, there are then two cells of identical genetic composition.

8. Now…On to our experiment... n Purpose: Identify varieties of bacterial colonies and investigate bacterial species diversity, by isolating, culturing, and analyzing bacterial colonies, or species, that inhabit: n Air n Pond Water n Raw Chicken n Washed/Unwashed hands n Keyboard n Soil Sample n Hypothesis: Knowing that bacteria can thrive in almost anywhere on our planet, we reason that all of the environments tested will grow bacterial species. We further hypothesize that the thumb print of the washed hand with the anti-bacterial soap, should house less species than any others tested, because the anti-bacterial soap should kill off all bacteria.

9. Methods n For chicken, soil, pond water, and keyboard samples, streak the plate using the streak plate method to isolate bacterial colonies. n Leave agar plate open for air sample. n For the unwashed hand gently press thumb against agar. n Take washed hand and gently press thumb against agar. n Wrap in Parafilm and incubate the cultures for about one week at 22 C. n Observe and Interpret Data n Figure 1. Streak Plate Method. (a) Streak the plate back and forth across top half of plate. (b) Rotate plate a quarter turn counter clockwise and streak top right quarter of plate. (c) Rotate plate a quarter turn counter clockwise and streak top right quarter of plate again. C. B. A.A.

10. Results: Soil 1 2 3 SIZESHAPE MARGINSURFACECOLOR 4 mmIrregularLobateWavyYellow/white 3 mmIrregularLobateWrinkledBrown/yellow 5 mmFilamentous WrinkledGreen/white

11. Results: Pond Water 1. 2. 3.

12. Results: Raw Chicken 1. 2. 3. 4.

13. Results: Air 1 2 3 4 5 6 1 7 5

14. Results: Washed Hand 1. 2.

15. Results: Unwashed Hand 1 2 3

16. Results: Keyboard 1. 2.

17. Control n An unopened agar nutrient plate, which ruled out agar contamination, had no bacteria species present.

18. Species vs. Environments

19. Conclusions/Observations nTnThe results supported our hypothesis since bacteria grew in all of our samples. nTnThe results did not support our hypothesis concerning the hand washed with anti-bacterial soap since it did not house less species than the other environments tested. nWnWe were surprised to learn that the air not only housed the most bacteria, but housed the most bacterial diversity of species as well.

20. Further Investigations… n Further studies can be conducted by using TEM microscopy, SEM microscopy, and gram staining, to specifically identify what type of bacterial species were present in each environment. n Research can also be conducted to figure out as to why the unwashed hand contained more bacteria than the washed hand. n Further research can be done to determine if any of the bacteria found in our samples are harmful to humans.

21. Questions to Ponder… n Do all bacteria grow at the same rate, and what factors in the environment contribute to determining their “carrying capacity?” n What research can be done to determine whether bacterial species and fungus compete with each other for nutrients and space in selected environments?

22. References n Coccoid-shaped Bacterium (causes skin infections), Enterococcus faecium (SEM x33,370). This image is copyright Dennis Kunkel at www.davidkunkel.com, used with permission. n Morgan, I.G. and Brown Carter, M. E., Investigating Biology: A Laboratory Manual for Biology. California: Benjamin/Cummings Publishing Co., Inc. 1993. n Rod-Shaped Bacterium, hemorrhagic E. coli, strain 0157:H7 (division) (SEM x22,810). This image is copyright Dennis Kunkel at www.davidkunkel.com, used with permission. n Spirilla- shaped Bacterium (SEM x33,370). This image is copyright Dennis Kunkel at www.davidkunkel.com, used with permission.

23. Gram stainNegative. MotilityMotile. HabitatOccurs naturally in soil and water as well as the intestine. Pathogenicity:Associated with urinary and respiratory tract infections, endocarditis, wound infections, and eye infections. Serratia marcescens

24. Gram-positive and gram-negative bacteria

25. Difference Between Gram-Negative and Gram-Positive Bacteria Gram-Negative BacteriaGram-Positive Bacteria More complex cell wall.Simple cell wall. Thin peptidoglycan celll wall layer.Thick peptidoglycan celll wall layer. Outer lipopolysaccharide wall layer.No outer lipopolysaccharide wall layer. Retain safranin.Retain crystal violet/iodine. Appear pink/red.Appear blue/purple.

26. Antibiotic Sensitivity Test

27. P10 C30 NA30 NB30S10 K30 E15 TE30 Ø20 Ø8 Ø14 Ø10 Antibiotic Sens i tivity Test

28. Hypothesis: Kanamycin is one of the most sensitive antibiotics because infections treated include respiratory tract, urinary tract, skin, soft- tissue and abdominal infections. Prediction: The size of the zone of inhibition is the largest. Results: The size of the zone of inhibition is the 2nd largest

29. Antibiotic Resistance Some bacteria have developed resistance to antibiotics naturally. Bacteria can become resistant to drugs in a number of ways. - Mutation. -Exchange genes with other bacteria. -Resistant traits spread to future generations quickly because of rapid reproducing.

30. Limitations n Reason unknown why S. marcescens is sensitive to certain medications. n Further research needed. Future Work n Develop new drugs to confront bacteria resistance. Mechanism n Antibiotics kill or stop the growth of harmful bacteria.