Patterns of Bacterial Growth: Difference between revisions

An agar plate demonstrating bacteria with strong chirality. Image courtesy of the laboratory of Prof. Eshel Ben-Jacob of Tel-Aviv University.

Introduction

How do patterns emerge in bacterial colonies?

In general, as environmental conditions become less favorable, the pattern of growth in a bacterial colony becomes more complex.

For the purposes of identifying patterns of growth, bacteria colonies can be through of as multicellular organisms. (info about communication)

Patterns of growth are a result of bacteria adapting their behavior to suit their environment.

Bacteria in the lab are grown specifically to isolate single colonies. Bacteria in the wild must cope with environmental conditions.

there are usually sharp transitions between morphotypes (Ben-Jacob)

Factors affecting growth

Taken from lacasta.

Agar density vs. nutrient density

concentration of agar controls how the bacteria move concentration of nutrients controls how fast the colony grows.

The larger the concentration of agar, the harder the resulting gel.

Bacterial growth patterns are compact at high nutrient densities, and become more fractals and peptone density decreases.

As agar density increases, the width of branches found in the fractal pattern of bacteria growth is thinner.

High nutrient level + mid-level agar = rings formed by expansion phases of bacterial growth.

If the concentration of agar is very high and the solution is very hard, then the bacteria cannot move. The colony grows in one spot, and grows radially when new bacteria are physically pushed from the center. (Lacasta) The resulting pattern of high agar concentration and high nutrient concentration is a colony with compact, concentric rings, and little to no branching. (Golding) If the nutrient level is low, then bacteria must rely on nutrients diffusing towards the colony. The resulting pattern of bacterial growth follows the diffusion-limited aggregation model.

Example of random walker movement and the first steps DLA lattice formation. Courtesy of Yale University.

Diffusion-limited aggregation

Diffusion-limited aggregation (DLA) is one growth model used to predict bacterial growth. It creates complex, multi-branched forms, and can be applied to any system where diffusion is the main method of particle transportation. It can be observed in bacterial growth on agar plates, dendrites, dust balls, electrodeposition, and mineral deposits.

To form a DLA pattern, begin with a seed molecule at the origin of the lattice. A "random walker" molecule diffuses from far away in a random pattern of motion. It stops once it reaches a space adjacent to the seed molecule, and another random walker is launched. In a DLA lattice, a molecule that sticks out of a main branch will not be rounded or smoothed over by new growth, but rather emphasized. Nodes are more likely to catch wandering particles because they three facets available for growth, compared to a molecule in the branch, which only has one facet.

Growth in an agar-dense, low nutrient environment is very slow. It takes approximately one month for bacteria to cover one petri dish. Growth rate increases along with nutrient density **possibly include in nutrient density section idk** (Lacasta).

Communicating walker model

The communicating walker model is used to explain how bacteria expand the boundary of their wetting fluid to move into previously unoccupied areas. In this model, the random walker is a particle made up of 1,000–100,000 bacterial cells located on the surface of the media. The walker's metabolic state is fueled by nutrients from the media, and is used to drive bacterial activities and metabolic processes. In a high concentration of nutrients, the internal energy increases until the walker divides. If there is not enough food for necessary activities, the internal energy of the walker drops to zero, and it is immobile. When active, walkers move in a random pattern, but are confined within the boundaries of the wetting fluid. If the walker attempts to make a movement that would put it outside the wetting fluid, the movement is not performed, but a count is added to that segment of the wetting fluid. Once the number of attempts on that segment reaches a certain threshold, the envelope is pushed out into the new area. The threshold bacteria need to meet to propagate the envelope is directly related to agar concentration, as harder agar requires more "attempts" to breach.

Other factors

Length of cells and handedness of flagella also affect how patterns form.

Chirality is a feature of bacteria which relates to symmetry. A bacteria with high chirality is not identical to its mirror image. Chirality in bacteria is often related to "handedness." It determines whether a bacterium's flagella will favor movement to the right or to the left. Chirality is observed when bacteria form swirling, hurricane-like patterns, either clockwise or counterclockwise on an agar plate.

Cooperation and Communication

what is cooperation?

Bacteria have developed cooperative behavior to cope with difficult environmental conditions. Bacteria communicate between individual cells and with the entire colony in order to cooperatively form patterns (Ben-Jacob). Generally, a higher lever of cooperation is observed when conditions are less favorable, such as in a high-agar or low-nutrient situation. (lacasta)

Bacteria are able to change the morphotype of their entire colony (for example, from branching to chiral) within a time period as short as 48 hours in order to better suit their environment. (Ben-Jacob) The ability of the colony to adhere to one morphotype and to transition completely to another are both characteristics of cooperative multicellular behavior and intercellular communication.

New features emerging from the model include various modes of cell-cell signaling, such as long-range chemorepulsion, short-range chemoattraction, and, in the case of the V morphotype, rotational chemotaxis.

(a) direct cell-cell physical and chemical interactions (34, 64); (b) indirect physical and chemical interactions, e.g. production of extracellular “wetting” fluid (44, 62); (c) long range chemical signaling, such as quorum sensing (41, 42, 55); and (d) chemotactic signaling [chemotactic response to chemical agents that are emitted by the cells (27, 30, 31)].

"In general, when environmental conditions are adverse (low nutrient or hard surface), a higher level of cooperation is observed." - lacasta

Conclusion

Overall text length should be at least 1,000 words (before counting references), with at least 2 images. Include at least 5 references under Reference section.

References

[Sample reference] Takai, K., Sugai, A., Itoh, T., and Horikoshi, K. "Palaeococcus ferrophilus gen. nov., sp. nov., a barophilic, hyperthermophilic archaeon from a deep-sea hydrothermal vent chimney". International Journal of Systematic and Evolutionary Microbiology. 2000. Volume 50. p. 489-500.

Matusushita, M., and Fujikawa, H. "Diffusion-Limited Growth in Bacterial Colony Formation". Physica A: Statistical Mechanics and its Applications. 1990. Volume 168, Issue 1, p. 498–506.

Eshel Ben-Jacob (1997) From snowflake formation to growth of bacterial colonies II: Cooperative formation of complex colonial patterns, Contemporary Physics, 38:3, 205-241

Witten, T. A., and Sander, L. M. "Diffusion-limited aggregation". Physical Review B. 1983. Volume 27, Number 9. p. 5686-5697.

• • • http://www.annualreviews.org/doi/full/10.1146/annurev.micro.52.1.779
    • http://arxiv.org/pdf/cond-mat/9904367v1.pdf

Edited by Eleanor Lopatto, student of Joan Slonczewski for BIOL 116 Information in Living Systems, 2013, Kenyon College.