Difference between revisions of "AY Honors/Bacteria/Answer Key/es"
(Created page with "</noinclude> <!-- 1. ¿Cuáles son las principales características de las bacterias que las distinguen de los otros seres vivos? -->") |
(Created page with "</noinclude> <!-- 5. Explicar las formas de reproducción de las bacterias. ¿Cuáles son las principales condiciones ambientales para que las bacterias puedan reproducirse? -->") |
||
Line 94: | Line 94: | ||
{{CloseReq}} <!-- 2 --> | {{CloseReq}} <!-- 2 --> | ||
{{ansreq|page={{#titleparts:{{PAGENAME}}|2|1}}|num=3}} | {{ansreq|page={{#titleparts:{{PAGENAME}}|2|1}}|num=3}} | ||
− | <noinclude> | + | <noinclude></noinclude> |
− | </noinclude> | + | <!-- 3. Dibujar las cuatro formas principales de las bacterias. --> |
− | <!-- 3. | ||
− | |||
− | + | {{clear}} | |
− | |||
− | |||
<div lang="en" dir="ltr" class="mw-content-ltr"> | <div lang="en" dir="ltr" class="mw-content-ltr"> | ||
Line 116: | Line 112: | ||
{{CloseReq}} <!-- 3 --> | {{CloseReq}} <!-- 3 --> | ||
{{ansreq|page={{#titleparts:{{PAGENAME}}|2|1}}|num=4}} | {{ansreq|page={{#titleparts:{{PAGENAME}}|2|1}}|num=4}} | ||
− | <noinclude> | + | <noinclude></noinclude> |
− | </noinclude> | + | <!-- 4. 4¿Qué son las bacterias gram negativas y gram positivas? --> |
− | <!-- 4. | ||
− | |||
<div lang="en" dir="ltr" class="mw-content-ltr"> | <div lang="en" dir="ltr" class="mw-content-ltr"> | ||
Line 125: | Line 119: | ||
</div> | </div> | ||
− | + | <noinclude></noinclude> | |
− | <noinclude | ||
− | |||
{{CloseReq}} <!-- 4 --> | {{CloseReq}} <!-- 4 --> | ||
{{ansreq|page={{#titleparts:{{PAGENAME}}|2|1}}|num=5}} | {{ansreq|page={{#titleparts:{{PAGENAME}}|2|1}}|num=5}} | ||
− | <noinclude> | + | <noinclude></noinclude> |
− | </noinclude> | + | <!-- 5. Explicar las formas de reproducción de las bacterias. ¿Cuáles son las principales condiciones ambientales para que las bacterias puedan reproducirse? --> |
− | <!-- 5. | ||
− | |||
<div lang="en" dir="ltr" class="mw-content-ltr"> | <div lang="en" dir="ltr" class="mw-content-ltr"> | ||
Line 206: | Line 196: | ||
{{CloseReq}} <!-- 5 --> | {{CloseReq}} <!-- 5 --> | ||
{{ansreq|page={{#titleparts:{{PAGENAME}}|2|1}}|num=6}} | {{ansreq|page={{#titleparts:{{PAGENAME}}|2|1}}|num=6}} | ||
− | <noinclude> | + | <noinclude></noinclude> |
− | </noinclude> | + | <!-- 6. ¿En qué consiste la alimentación y respiración de las bacterias? --> |
− | <!-- 6. | ||
− | |||
<div lang="en" dir="ltr" class="mw-content-ltr"> | <div lang="en" dir="ltr" class="mw-content-ltr"> |
Revision as of 04:47, 5 April 2021
1
Bacteria are single cell organisms (though some do form chains or other colonial groupings, each individual remains its own organism).
The have no membrane around their internal organelles - so rather than a nucleus containing genetic material, which has its own membrane keeping it separate from the rest of the cell contents, bacteria have a nucleoid, without a distinct membrane.
All but one group of bacteria have both a cell membrane and a cell wall.
The genetic material in a Bacteria is in a tangled loop in the nucleoid
Many bacteria also have loops of genetic material, called Plasmids, that can serve to transfer genetic information between organisms, and may provide new or useful characteristics for a bacteria, which in part explains why they are able to adapt so quickly as species.
2
Some structures of bacteria
Capsule (Slime Layer): Provides protection, as well as may serve for adhesion (sticking the cell to something)
Cell Wall: Provides form, structure and protection. There are two different basic structures of cell walls in Bacteria. One is a cell wall made of a relatively thick layer of Peptidoglycan (carbohydrates and proteins). The other has an additional outer layer that includes carbohydrates, proteins and lipids (fats).
Cell Membrane: The boundary of the cell, selectively permeable to allow certain molecules and gasses to pass through.
Ribosome: The organelle responsible for protein synthesis
Plasmid: A ring of genetic material separate from that within the nucleoid
Nucleoid: The location of the genetic material of a bacteria
Cytoplasm: The “goo” inside the cell, in which the organelles and all other content exist.
Inclusion Body: Non-membranous granules in the cytoplasm used to store materials
Gas Vacuole: In some water-borne bacteria, small gas filled pockets used for bouyancy
Pili: microscopic tubes on some bacteria, used for attachment, or as a way to connect two bacteria to transfer genetic material
Flagellum: A hair- or whip-like appendage, used for motility
Endospore: A hard-cased spore produced by a bacteria often to assist in survival of hostile environment.
3
Two main types are Cocci (roughly spherical) and Bacilli (rod-shaped).
Other forms include the comma-shaped Vibrios, and two types of corkscrew-shaped bacteria, the rigid Spirilla and the flexible Spirochetes.
4
As noted above, bacteria have two types of cell walls. One is a cell wall made of a relatively thick layer of Peptidoglycan (carbohydrates and proteins). The other has an additional outer layer that includes carbohydrates, proteins and lipids (fats). Hans Christian Joachim Gram, a Danish bacteriologist, developed a staining method to rapidly identify which of these two basic cell walls a bacteria possesses. The bacteria with the first type of cell wall are stained using Gram’s method, those of the second type are not stained. Thus the former are referred to as Gram Positive bacteria, the latter Gram Negative. The Gram test is often one of the first performed to help identify a particular bacteria colony.
5
Different types of bacteria have different environmental requirements for reproduction, but in general bacteria usually need warm locations with plenty of their particular nutrients readily available.
Most bacteria reproduce through binary fusion, a form of asexual reproduction. In this process, the bacteria creates a duplicate set of genetic material, the genetic material moves to each end of the bacteria, and the cell then squeezes in half, creating two effectively identical bacteria cells.
There are also a few variations of asexual reproduction in different groups of bacteria.
Some Cyanobacteria produce Baeocytes, enlarged bacterial cells that have rapid multiple division internally before breaking open and spewing out numerous new bacteria.
Certain bacteria may reproduce through budding, a process where a small bud forms on a parent bacteria, genetic material is transferred to the bud, and then it separates.
Some bacteria, including some of the Firmicutes bacteria, create two complete daughter cells inside the parent, then the parent breaks open and dies, releasing the two new bacteria cells.
Given that bacterial reproduction is primarily through forms of fission (division), there is no change in genetic material aside from mutation. However, Bacteria do have other ways to transfer genetic material, though not quite analogous to sexual reproduction.
Conjugation: Bacteria transfer genes (usually on plasmids) via their pili.
Transduction: A bacteriophage (a virus that uses bacteria as a host) may pick up some pieces of genetic material from a previous host and incidentally transfer it into a new bacterial host.
Transformation: Bacteria may pick up fragments of genetic material from their environment, usually left by dead bacteria.
6
Bacteria may be Autotrophs (roughly meaning self-food) or Heterotrophs (roughly meaning different-food). Autotrophs are capable of acquiring carbon from inorganic sources (usually in the form of Carbon Dioxide), Heterotrophs must consume some organic materials (sugars, fats, starches, etc) for the uptake of carbon.
Categories of Autotrophs:
Photoautotrophs (light-self-feed) are capable of photosynthesis, using sunlight as part of the process to take up nutrients from their environment. Some may be able to draw on sulfur compounds, or acidic hydrogen compounds. Among the photoautotrophs are the green and the purple photosynthetic bacteria, neither of which produce oxygen as a byproduct, and the cyanobacteria, the so-called blue-green bacteria (though some taxonomists place these in their own category separate from other bacteria).
Chemoautotrophs (chemical-self-feed) are those that can produce their own organic compounds, but do not necessarily need sunlight as a precursor. Some of the bacteria at the base of the food chain near deep sea hydrothermal vents are chemoautotrophs. Different chemoautotrophs utilize different “foods,” including iron, ammonia, nitrite, sulfur and hydrogen gas. Some of the most important are those that can convert nitrite (NH3) into a form of nitrogen that plants can absorb. This process is called nitrification, or more commonly nitrogen fixing. Some bacteria capable of fixing nitrogen are considered chemolithotrophs, able to effectively live on rock as a substrate.
Categories of Heterotrophs:
Saprophytes (dead-feed) are the bacteria that break down organic matter into simpler molecules. These are the decomposers, as well as many of the beneficial bacteria in the guts of animals (including people). Some are capable of breaking down cellulose or other plant-based materials that human digestive systems cannot.
Parasitic bacteria are those that draw nutrients directly from a host. Rickettsia and Chlamydia, two disease-causing bacteria, must live inside animal cells, and are examples of parasitic bacteria.
Respiration:
Bacteria, whether autotrophs or heterotrophs, may be either Aerobic (requiring oxygen as part of their respiration) or anaerobic (either not requiring oxygen, or being unable to grow in the presence of atmospheric oxygen). Bacteria that require oxygen for their metabolic functions are called obligate aerobes, while those that cannot live in the presence of oxygen are called obligate anaerobes. Between them there are different gradations of oxygen tolerance. Microaerophyllic bacteria live best in low-oxygen environments. Facultative anaerobes are capable of living without oxygen, but thrive in the presence of oxygen. And aerotolerant anaerobes are those that live best without oxygen, but are generally unaffected negatively by the presence of oxygen.
7
There are many harmful bacteria, impacting humans, animals and plants. As question 10 discusses illnesses caused by bacteria, more attention can be given in this question to bacteria that are “harmful” in other ways.
Some examples of harmful bacteria include:
Bacillus anthracis (Anthrax) - often found in soil, the spores can lead to death in cattle if ingested.
Clostridium botulinum (Botulism) - A bacteria that produces a neurotoxin as a byproduct of its metabolic process - it is often a cause of food poisoning.
Streptococcus sp. (Strep) - A bacteria that is usually always present in small amounts in humans, when the immune system is weakened (through surgery, through cold or fatigue, or for other reasons), there can be rapid growth and damage, potentially leading to strep throat, pneumonia or other illnesses.
8
There are numerous beneficial bacteria, from those within our own intestines to the myriad decomposers that help break down and recycle organic matter, to bacteria used in food production.
Nitrosomonas sp. (Nitrogen fixers) - As mentioned earlier, some bacteria in the soil or in water are able to break down nitrites and ammonia, converting the nitrogen into forms that can be utilized by plants.
Bacteroides sp. (Gut flora) - Bacteroides are among the many different bacteria living in our intestines, breaking down complex molecules that our bodies are not capable of breaking down, and freeing some of those nutrients for our body to absorb.
Lactobacillus sp. - These are some of the many types of bacteria used in the cheese making process, converting milk into cheese through the breakdown of lactose.
9
If we assume the word “leprosy” in the Bible refers to the modern disease leprosy, then these are all stories about a disease caused by the bacteria Mycobacterium leprae. Among these are the story of the healing of Naaman in 2 Kings 5, or examples of Jesus healing lepers, as in Luke 17 and Mark 10.
10
Below are some examples. Consider bacterial illnesses that may occur in your area, or in places you may travel to (for missionary service, perhaps).
Typhoid Fever (Salmonella typhi) - Transferred through contaminated water.
Prevention: Vaccination. Also, for the unvaccinated, in areas where Typhoid may be present, it is best not to consume fresh fruits and vegetables that have been washed with untreated water, and best not to drink water that isn’t bottled (also be wary of ice, as it is usually made from local water).
Cholera (Vibrio cholera) - Transferred through water contaminated with bodily fluids.
Prevention: In areas where cholera may be prevalent, wash hands thoroughly, avoid fresh fruit or vegetables unless you can peel them yourself, only eat cooked food, do not drink the local water.
Tetanus (Clostridium tetani) - Transferred through contamination into wounds.
Prevention: Vaccination (note that tetanus vaccinations need updated relatively frequently compared to many other types of vaccinations) Also, be careful around rusty and dirty objects that can cause puncture wounds or cuts. Wash wounds thoroughly and apply a surface antiseptic. Leave deeper wounds open to drain (seek medical attention as appropriate).
Tuberculosis (Mycobacterium tuberculosis) - Transferred through droplets in coughs and sneezes.
Prevention: Use caution in areas where tuberculosis is common. Wear face masks, wash hands, do not touch hands to face or mouth, try to avoid enclosed spaces with those that may be infected, work in open, well ventilated areas.
Lyme Disease (Borrelia burgdorferi) - Transferred through the bite of certain ticks.
Prevention: Avoid or use caution in areas that may be infested with ticks (tall grasses, thick undergrowth, etc). Wear long pants and long sleeves, tuck pant legs into boots or socks, use insect repellents with DEET, check frequently for ticks, remove ticks carefully, apply surface antiseptic.
11
As noted above, bacteria have a unique strategy to ensure genetic variability - the presence of plasmids. In any given colony of bacteria, there are likely to be a few mutants that may survive an otherwise toxic situation (such as the presence of a certain anti-biotic). Those that survive will pass the trait on to their offspring through binary fission, but may also pass it on to other types of bacteria via the plasmids. Given the rapid pace of bacterial reproduction, this can relatively quickly lead to the development of antibiotic-resistant bacteria. Each time they develop one resistance, a different antibiotic is necessary to treat an infection. The overuse of antibiotics can accelerate the genetic transformation of bacteria, leading to new forms that become resistant to all common antibiotics, and thus making them more dangerous.