body cavity type (no body cavity at all!): ectoderm -> various tissues (mesoderm) -> endoderm (gut); organs have direct contact with epithelium; Blastocoel fills up with mesoderm in form of muscle fibers, parenchyma, and other tissues. 

Ex: flatworm

"false cavity": organs held together loosely but no organization; blastocoel persists in adults leaving a space between the digestive tract and the body wall. The mesoderm separates from the endoderm and connects to the body wall in the form of longitudinal muscles and connective tissue

Ex: roundworm

cum (with), mensa (table); meaning eating at the same table; heterospecific ass., not obligatory, often for shelter, defense or food getting; defined as regular & close heterospecific ass. in which 1 partner (commensal) gains some benefit while other partner (host) not benefitted but also not disadvantaged; derives some physical shelter from host & there is not metabolic dependence of commensal on its host

Ex: ciliated protozoan - clam colonial coelenterate - tubeworms sea anenome - hermit crab

meaning both equally. It is defined as a bilaterally advantageous heterospecific association where both partner (the mutuals) are metabolically dependent on each other. This is usually an obligate relationship

Ex: green hydra - green algae giant clam - green algae medical leech - pseudomonas hirudenis flagellate - woodroach

Older definitions were generally based on harm. It is currently defined as an intimate heterospecific association, temporary or permanent, where there exists some metabolic dependence of one partner, the parasite, on the other partner, the host. If harmful, the parasite is said to be pathogenic. Metabolic dependence may be in the form of nutritional materials, digestive enzymes, developmental stimuli, imaturation control, etc

Ex: sheep liver fluke - cattle/sheep unionid clam - a variety of fish trichinella spiralis - man/pigs/rodents

-Air in and around cities became murky and irritating to people's eyes, skin and respiratory systems

–Effects of air, land and water pollution was seen in the wild populations (decline of populations of birds, mammals, etc.)

–Drastic atmospheric changes

–Loss of biodiversity

–In winter, freshly fallen snow turned grey from soot from city chimneys

–Rivers and beaches became increasingly fouled by raw sewage, garbage and chemical waste

Human pop growth; With increased populations there is increased consumption of resources, increased pollution and increased habitat alteration.

–Ground water supplies being depleted

–Soils degraded at an increasing rate

–Oceans over harvested

–Oil resources drawn down

–Mineral resources depleted

–Forest cut faster than they can re-grow

–Atmospheric changes caused by Man

•Global trends currently not sustainable

•Current trends on collision course with basic human needs and the fundamental system that maintains our planet as a tolerable place to live

•A finite planet can not go on adding 90 million people each year while:–Soils are being lost –The atmosphere is changing –Species are being lost –Water is being depleted

Organization of living organisms in an ecosystem into groups based on similarities in feeding relationships

–Producers = Photosynthesis (Chlorophyll)

–Consumers = Feed on other organisms

–Decomposers = Organisms that break down organic material

C4 = Man (top carnivore)

C3 = Trout

C2 = large insect larva

C1 = Copepods

P = Algae

producers (green plants) ->

primary consumer (herbivores) ->

secondary consumer (predators).

lost as heat; 2 consequences:

1) less enegry is available at ea. successive trophic level 2) length of food chain is limited (not much energy left after 3-4 steps)

the capacity of an organism to withstand or adjust to any disturbed conditions in the environment.

EX: stenohaline vs. euryhaline, stenothermal vs. eurythermal

(1) Tundra

(2) Boreal (north) forest

(3) Temperate Deciduous Forest

(4) Temperate Grassland

(5) Desert

(6) Mediterranean Scrub Forest

1. population level

2. ecosystem level

(1) NATALITY OR RECRUITMENT (adds new individuals)

(2) GROWTH (adds biomass to a population)

(3) MORTALITY (individuals are lost from a population)

(4-5) Immigration and emigration

the production of new individuals born in a population -Generally biologists use a time frame to measure this parameter, hence, it becomes a rate function.

EX: the number of whiptail lizards added to a population in a year.

Those factors whose effect is not related to population density; Seen more at periphery of sp range.

EX: abiotic factors, fire, climate, hurricanes, floods, pesticides.

Those factors whose effect is a function of population density.Seen more in central portion of spp range.

EX: biotic factors, predation, food limitation via competition, diseases.

(1)mortality caused by biotic and abiotic ecosystem processes

(2)(natural causes)

EX: predation, parasitism, disease, accidents, starvation, etc.

a. If target population is low, hunters may “switch”.

b. Harvest regulations may limit access to populations.

c. A species may increase natality or recruitment in responseto additive mortality.

d. Movement into “hurting” population by others from high density populations.

rN =dN/dT

r = max growth rate

N = # of individuals in a pop

dN = change in #

dT = change in time

rN (K-N)/K=dN/dT

r = maximum growth rate

N = # of individuals in a population

dN = change in number

dT = change in time

K= maximum # of individuals environment can sustain

(= carrying capacity)

The relative numbers of each sex in a wildlife population. Ratios are expressed as percentage of males to percentage of females.

(EX: 55:45 = 55% males 45% females).

1. age of sexual maturity of males & females

2. age of first breeding

3. Sex ratio

4. Survivorship by sex

5. Number of young per breeding

6. Length of gestation period

7. Is sp. monogamous or polygamous

8. # of females that breed at each age

9. Influence of nutritional condition on reproduction