Microbiology with Lab: A Fundamental Approach
Task 2: Unknown Lab Manual 9
Objective of Task 2
The primary goal of Task 2 in this microbiology laboratory exercise is to accurately identify an unknown bacterial species by utilizing a constrained set of laboratory tools and diagnostic tests, reflecting real-world limitations in lab settings. This task enhances critical thinking and problem-solving skills by encouraging students to interpret laboratory data, make strategic decisions on which tests to conduct next, and ultimately confirm the organism’s identity. The process fosters analytical reasoning and decision-making, which are essential for understanding the complex biological interactions involved in microbial identification.
Task Instructions
Welcome to the Unknown 9 Lab! Your challenge is to methodically apply a series of laboratory tests to pinpoint the identity of an unknown bacterial species. Before starting, ensure you select the correct organism group, which is determined by the first letter of your last name. Since resources and time in laboratory settings are limited, it is neither feasible nor necessary to run every possible test on all samples. Instead, use the decision tree provided to guide your selection of diagnostic tests, systematically narrowing down the list of potential organisms until you achieve a final identification.
Your lab report should emphasize the Gram stain and two additional diagnostic tests chosen based on the decision tree and your prior results. Each test selected must be clearly justified in your report. After completing the identification, analyze the Kirby-Bauer antibiotic sensitivity test results to recommend an effective antibiotic therapy.
Investigation Tools
Before commencing your investigation, review Section 4, Lesson 2, which explains the Gram staining procedure and the decision tree that will assist you in choosing diagnostic tests.
Please save your completed lab report as a Word document titled D311 Task 2 Lab Report [Last Name]. Clearly indicate the unknown organism number to enable prompt evaluation.
Lab Procedure Overview
Initial Step: Gram Stain
Begin by performing a Gram stain to classify the bacterium as either Gram-positive or Gram-negative. Observe the cell morphology to determine if the bacteria are rod-shaped (bacilli) or spherical (cocci).
| Question | Answer |
|---|---|
| Is the organism Gram-positive or Gram-negative? | Determine based on stain color: purple indicates Gram-positive bacteria with thick peptidoglycan walls; pink/red indicates Gram-negative bacteria with thinner walls and outer membranes. |
| What is the morphology of the organism? | Identify cell shape under the microscope: bacilli are rod-shaped, and cocci are spherical. |
Next Test Selection
Following the Gram stain, utilize the decision tree to select the next diagnostic test. Test choices should be based on previous results and evidence to effectively narrow down possible bacterial species. The decision tree includes various tests such as endospore staining, catalase, glucose fermentation, citrate utilization, blood agar hemolysis, capsule staining, motility, lactose fermentation, Voges-Proskauer, coagulase, and Kirby-Bauer antibiotic sensitivity.
Detailed Tests and Interpretations
Endospore Stain
This test identifies the presence of endospores, highly resistant structures formed by some bacteria.
| Question | Response |
|---|---|
| What colors are observed in the stain? | Typically, spores appear green while vegetative cells stain pink/red. |
| Does the organism form spores? | Confirm the presence of spores if green structures are visible within or outside cells. |
| What is the next test chosen? | Select the next test based on the presence or absence of spores following the decision tree recommendations. |
Capsule Stain
Capsule staining reveals if the bacterium produces a polysaccharide capsule, which appears as a clear halo around the cell.
| Question | Response |
|---|---|
| Is there visible space around cells? | A clear halo indicates capsule presence. |
| Does the organism form a capsule? | Confirm capsule production if halos are observed surrounding the cells. |
| What is the next test chosen? | Choose subsequent testing based on capsule presence and decision tree guidance. |
Blood Agar Growth and Hemolysis
Blood agar tests for bacterial growth and hemolytic activity, which can be alpha (partial), beta (complete), or gamma (none).
| Question | Response |
|---|---|
| Is there bacterial growth? What is the color? | Describe colony growth and coloration patterns on blood agar. |
| What type of hemolysis is observed? | Identify hemolysis type: alpha shows greenish discoloration, beta shows clear zones, gamma shows no change. |
| What is the next test chosen? | Explain the next diagnostic step based on hemolysis patterns and decision tree suggestions. |
Citrate Test
This test determines the organism’s ability to use citrate as its sole carbon source, indicated by a medium color change.
| Question | Response |
|---|---|
| What is the color of the medium? | Record color after incubation; a color change from green to blue typically indicates citrate utilization. |
| Are results positive or negative? | Interpret positive if blue, negative if green or no change. |
| What is the next test chosen? | Justify next test selection based on citrate utilization results. |
Voges-Proskauer Test
This assay detects acetoin production, a metabolic byproduct, by a color change in the reagent tube.
| Question | Response |
|---|---|
| What color is the reagent tube? | A pink/red color after reagent addition indicates a positive result. |
| Are results positive or negative? | Interpret positive if color change occurs, negative if no change. |
| What is the next test chosen? | Select the next test based on metabolic information from this assay. |
Glucose Fermentation Test
This test measures whether the bacterium ferments glucose, sometimes producing gas.
| Question | Response |
|---|---|
| What color is the tube? Is gas produced? | Color changes to yellow typically indicate acid production; gas presence is noted by bubbles or cracks. |
| Are results positive or negative? | Positive if acid or gas production observed; negative if no change. |
| What is the next test chosen? | Explain next test choice guided by glucose fermentation results. |
Lactose Fermentation Test
This test is similar to glucose fermentation but focuses on lactose metabolism.
| Question | Response |
|---|---|
| What color is the tube? Is gas produced? | Note color change and gas presence similar to glucose test. |
| Are results positive or negative? | Positive if acid or gas production observed; negative if unchanged. |
| What is the next test chosen? | Support next testing based on lactose fermentation outcome. |
Catalase Test
Catalase activity is determined by the appearance of bubbles when hydrogen peroxide is added, indicating peroxide breakdown.
| Question | Response |
|---|---|
| Were bubbles observed? | Yes indicates catalase positive; no bubbles indicate negative. |
| Are results positive or negative? | Positive catalase activity suggests aerobic metabolism; negative suggests anaerobic or microaerophilic. |
| What is the next test chosen? | Select next test based on catalase results and decision tree guidance. |
Coagulase Test
This test identifies coagulase enzyme production, which causes plasma clotting.
| Question | Response |
|---|---|
| Was the tube liquid or clumped? | Clumping indicates positive coagulase activity; liquid indicates negative. |
| Are results positive or negative? | Positive if clumping; negative if liquid remains uniform. |
| What is the next test chosen? | Determine next test based on coagulase presence according to the decision tree. |
Motility Test
Motility is assessed by whether bacterial growth spreads diffusely or remains confined.
| Question | Response |
|---|---|
| Was the growth diffuse or defined? | Diffuse growth indicates motility; defined growth indicates non-motility. |
| Are results positive or negative? | Positive if motile; negative if non-motile. |
| What is the next test chosen? | Choose next step based on motility results. |
Kirby-Bauer Diffusion Test
This test evaluates the bacterium’s susceptibility to various antibiotics. The results guide appropriate antibiotic treatment choices.
| Question | Response |
|---|---|
| What is the resistance profile to each antibiotic? | List susceptibility or resistance for each antibiotic tested based on zone of inhibition measurements. |
| Which antibiotics are unsuitable for treatment? | Identify antibiotics where resistance was observed and thus should be avoided. |
| Which antibiotic is optimal for treatment? | Recommend the antibiotic(s) to which the bacterium shows susceptibility for effective clinical therapy. |
Summary
The identification of unknown bacteria in clinical microbiology demands a systematic and evidence-based approach. Starting with the Gram stain to categorize bacteria, a decision tree effectively directs the selection of further diagnostic tests, optimizing the use of limited laboratory resources and enhancing diagnostic precision. Confirmatory tests narrow down the organism’s identity, while the Kirby-Bauer antibiotic sensitivity test informs appropriate treatment options. This structured methodology integrates practical lab skills with critical analytical thinking to ensure accurate bacterial identification and support clinical decision-making.
References
Cappuccino, J. G., & Welsh, C. T. (2017). Microbiology: A Laboratory Manual (11th ed.). Pearson.
Madigan, M. T., Bender, K. S., Buckley, D. H., Sattley, W. M., & Stahl, D. A. (2018). Brock Biology of Microorganisms (15th ed.). Pearson.
D311 Task 2: Identifying Unknown Microorganisms in Lab 9
Western Governors University. (n.d.). Microbiology with Lab: A Fundamental Approach. Task 2 Unknown Lab Manual.