Some members of Kingdom Protista
are unicellular, others are colonial, and yet others are multicellular. Note
that in the colonial forms, all the cells are similar with similar, generalized
functions, whereas in the truly multicellular species, the “body” of the
organism consists of a variety of types of cells, each type with its own
specialized function. These organisms are all eukaryotes (they have a true
nucleus). They all need some kind of a water-based environment--which can be
fresh or marine water, snow, damp soil, polar bear hairs--in which to live. All
are aerobic and have mitochondria to do cellular respiration, and some have
chloroplasts and can do photosynthesis. Most of them reproduce or grow by
mitosis, and some reproduce by meiosis and fertilization. Many can form cysts
in adverse conditions. Protists are a major component of plankton.
Protists are grouped into three major, unofficial
categories based on means by which they obtain nutrition. These are the Protozoa,
the Algae, and the Fungus-like Protists. For some reason,
botanists use the word “Division” to mean the same taxonomic level as “Phylum”,
and since, way back everything was lumped in as either a plant or an animal,
taxonomists who study Kingdom Protista (and those who study Kingdom Fungi) also
still use the word “Division” to mean “Phylum”, so for example, when “Division
Rhizopoda” is listed below, that means the same thing as saying “Phylum
Rhizopoda”.
These protists are animal-like, especially in their
nutrition. They ingest their food by phagocytosis.
Some have mouth-like structures into which the prey is put while others use pseudopodia
to move and to engulf prey. Typical prey include bacteria and other smaller
one-celled organisms.
Division Rhizopoda:
An example
of a member of this Division is genus Amoeba,
a fresh-water dweller. Protists in this group are unicellular and have
pseudopodia. Some secrete shells around themselves, while others do not. None
of them have flagella, cilia, or meiosis. Entamoeba
histolytica is a parasitic
form that causes amoebic
dysentery. These colonize the colon and feed on bacteria, causing
symptoms that range from mild diarrhea to dysentery. Typically periods of
watery diarrhea, often containing blood, may alternate with constipation, and
often there is flatulence and abdominal cramping. Entamoeba can be
directly spread (anal sex), or indirectly spread (by drinking contaminated
water). Fresh fruits and vegetables may be unsafe if fertilized with human
feces, watered with contaminated water, or prepared by a person with it on
his/her hands.
Division Apicomplexa:
These are
all parasites and form tiny, infectious spores. All have complex life cycles.
An example is Plasmodium
vivax, which causes malaria,
for which certain species of mosquitoes are the secondary host. It is also
possible to become infected with Plasmodium parasites from a transfusion
from an infected person or if a drug addict shares a syringe with an infected
person. One stage in this complicated life cycle grows in the mosquito, the
next stage in the newly-infected person’s liver, and the next stage invades the
person’s red blood cells, rupturing the RBCs as the parasites leave to invade
other cells. Symptoms include cyclical alternating chills, fever, and sweating
which at first, can be mistaken for flu. While usually less than 1% of the RBCs
are infected, often malaria causes anemia due to the smaller number of RBCs.
Often the spleen and liver become enlarged as they try to deal with the dying
RBCs. Malaria is treated with extract from the quinine tree. Remember that
people with sickle-cell are more resistant because when a malaria parasite
enters a RBC, the RBC sickles, killing the parasite, thereby preventing it from
multiplying and spreading.
Division Zoomastigophora:
This
Division contains some organisms which are free-living, others which are symbionts,
and yet others which are parasites. An example of a symbiotic member of this
Division is the protozoans which live in the gut of termites and digest
cellulose in the wood the termites eat. An example of a parasitic form would be
Trypanosoma
gambiense, which causes African sleeping sickness and is
spread by the bite of the tsetse fly. Symptoms include irregular fever, general
swelling of the lymph nodes, skin eruptions, and areas of painful local
swelling. Eventually CNS symptoms like tremors, headache, apathy, and
convulsions appear and become worse, leading to eventual coma and death. Early
on, the parasites are found in blood and lymph, but later only in the person’s
cerebrospinal fluid.
Division Ciliophora:
An example of an organism in this
Division is Paramecium.
These protozoans are solitary, fresh water organisms and use cilia to move.
They have probably the most complex structure and organization of all cells.
Rather than one nucleus, they have a larger macronucleus and several
smaller micronuclei. They use a form of sexual reproduction called conjugation
in which some of the micronuclei are exchanged between the two individuals
involved.
Algal
Protists
These protists are photosynthetic; their nutrition is
plant-like. Almost all of them have chlorophyll A, most have chlorophyll C, but
only a few have chlorophyll B. They also have a variety of carotenoids and
other pigments, and frequently they are grouped into Divisions based on
similarities in pigments.
Division Dinoflagellata:
These are
abundant in plankton, occasionally occurring in large numbers. They can
occasionally become so numerous that the water looks red, thus this algal
bloom (meaning there are large numbers of them, having nothing to do with
flowers, which they do not have) is called Red Tide. Because
Dinoflagellates are toxic to humans, it is not safe to eat “shellfish” (clams,
etc.) collected where Red Tide is occurring (the Protists get inside the clam
shell and cannot be easily removed). Dinoflagellates are bioluminescent,
that is, they are able to produce light like lightening bugs, and at night
during Red Tide, the crests of the ocean waves appear to glow in the dark.
Division Euglenophyta:
Probably the best-known example
of this Division is genus Euglena.
Each of these organisms has a flagellum
on its anterior
end, and this is used to propel the organism. They have chloroplast and, when
in the light, do photosynthesis. If they are not in the light, they can also
obtain nutrition by phagocytosis. To help them sense light (which they then
move toward), Euglena have a light-sensitive “eyespot” or stigma
near their anterior ends. This is not a true eye, in that it cannot do any
image formation, but rather it is a photoreceptor
which senses the light level in the organism’s environment.
Division Chlorophyta:
These
protists are also known as the “green algae.” Their chloroplasts and the
pigments therein are similar to plants (this is about the only group of algae
with chlorophyll B), thus it is thought that the green algae may be the
evolutionary ancestors of plants. Various species of green algae may be found
in a variety of environments including both fresh and salt water, damp soil,
the surface of snow, and within other organisms (lichens, hydra, polar bear
hair).
Chlamydomonas
are unicellular and contain an eyespot (stigma), a chloroplast, two flagella,
and a nucleus.
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Volvox
are colonial and often contain darker green daughter colonies inside. Each
cell posesses two flagella, enabling the colony to be mobile. There is an intercellular
matrix holding the colony of cells together.
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Ulva
is called Sea Lettuce. This is truely multicellular, with a division of labor
among the various cells, and is macroscopic. The “body” is two cells thick,
and there is a specially-modified “holdfast” to anchor the organism to the
ocean floor. Its life cycle includes both 1n and 2n stages (see below).
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Closterium
is a member of the sub-group called the Desmids. Some desmids form
colonies, but Closterium is solitary. Its nucleus is in the center with a
cone-shaped chloroplast on each side. Each chloroplast contains a series of
starch-storage organelles called pyrenoids
In living Closterium, each end of the cell bears a small vacuole containing
several gypsum grains which “dance” by Brownian motion.
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Spirogyra
are colonial, being organized into long filaments. Each cell contains a
spiral chloroplast with pyrenoids (used to store starch) and a nucleus. They
have conjugation--a
type of sexual reproduction in which the contents of the male gamete cell go
over into the female cell.
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Many green algae, especially the multicellular ones, have both sexual and asexual stages in their life cycles, thus we must re-introduce the idea of Alternation of Generations we discussed along with meiosis. When we first discussed Alternation of Generations, we looked at a very simple diagram in which adults produced 1n gametes by meiosis, and those gametes joined by syngamy to form a new 2n generation. In reality in algae and plants, there are a few more stages in the process, thus we now need to re-visit this cycle. The 2n generation, which in humans is called an “adult,” in algae and plants is called a sporophyte because it produces spores. Within specialized reproductive structures in/on the bodies of the sporophyte, meiosis occurs to reduce the chromosome number from 2n to 1n, thus the spores which are produced are 1n. Each spore germinates and grows into a new, independent, 1n organism (which often looks totally different than the 2n generation). These 1n organisms are called gametophytes because they produce the gametes (eggs and sperm), which are still 1n. An egg and sperm unite by syngamy increasing the chromosome number from 1n to 2n, and forming a zygote which is 2n. The zygote grows into the sporophyte, and the cycle starts over. Various of the green algae go through this cycle as do members of the next two groups, the brown and red algae. Plants also go through this same cycle with some interesting modifications we will discuss later.
Division Phaeophyta:
These
organisms are commonly known as the “brown algae.” They are multicellular and
live in marine, temperate zone, costal areas. They all have a form of sexual
reproduction with alternation of generations. One member of this Division with
which you may be familiar is Kelp, which actually can be any of several
species of seaweed in the genera Fucus and/or Laminaria. Brown
algae are used in many cultures as human food, and are good sources of iodine.
We need iodine for our thyroid glands, and if a person doesn’t enough iodine in
his/her diet (most commonly in inland areas where iodine is not added to salt),
the thyroid gland enlarges in an attempt to keep making enough thyroid hormone
(which doesn’t do any good because what it’s lacking is the iodine needed to
make the hormone). This enlarged thyroid is called a goiter. Laminaria
also has an interesting gynecological use. If a woman is scheduled for
some medical procedure for which the doctor needs access to the inside of her
uterus, often a day or so beforehand, rolled-up, dried pieces of Laminaria
are inserted into the opening of the woman’s cervix. As the seaweed absorbs
water from her body fluids, it gently and slowly expands, gradually stretching
the cervix. Thus, by the time her surgery is scheduled, her cervix has been
dilated slowly and gently rather than the doctor having to forcibly and quickly
(thus painfully) stretch the cervix open minutes beforehand.
Division Rhodophyta:
These are
called the “red algae.” They also are multicellular and marine-dwelling, but
are more typically found in tropical zones and deeper in the ocean. They also
go through alternation of generations, Many of these (such as the Nori used in
sushi) are used by humans as food, and are also good sources of iodine.
Fungus-like
Protists
Division Myxomycota:
These
organisms are called “slime molds.” They are fungus-like in their nutrition in
that they absorb nutrients from their environment. Their “body” structure is
unusual in that the nuclei undergo mitosis, but there is no cytokinesis--there
are no individual cells with one nucleus each. Rather, the “body” is a giant,
multinucleate mass of cytoplasm. Slime molds are mobile: they move by amoeboid
movement, in other words, like a giant Amoeba with giant pseudopodia. They
live in decayed wood and move around in between the fibers, ingesting bacteria,
etc. by phagocytosis. Slime molds are often brightly-colored (yellow or
orange).
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