Organisms need energy in the form of ATP to survive
The energy stored in ATP comes from other organic molecules,such as carbohydrates, and is transferred during the process of respiration
The method by which an organism gains organic molecules to fuel respiration is known as its mode of nutrition
There are two main modes of nutrition; autotrophy and heterotrophy
Autotrophs
An autotroph synthesises, or produces, its own organic molecules from simple inorganic substances in its environment
Photosynthetic organisms use light energy to convert carbon dioxide from the air into organic molecules such as carbohydrates
Some autotrophs use energy from the oxidation of inorganic compounds instead of light energy
Autotrophs that use light energy are known as photoautotrophs, while those that use energy from oxidation of chemicals are known as chemoautotrophs
Because autotrophs make their own organic molecules without relying on other organisms, they are known as producers
Most green plants are autotrophs, along with algae such as seaweeds, and photosynthetic bacteria such as cyanobacteria
Heterotrophs
Heterotrophic organisms gain their organic molecules by ingesting the tissues of other organisms
There are several types of heterotroph, including consumers, detritivores, and saprotrophs
Mixing modes of nutrition
Some organisms are able to make use of more than one mode of nutrition, such as auto- and heterotrophy
These organisms are referred to as mixotrophs
Euglena is a single-celled eukaryotic organism that makes use of both autotrophy and heterotrophy
Euglena cells can take in bacterial cells by endocytosis, and then digest them using digestive enzymes stored in lysosomes
Euglena cells also contain a light-sensitive spot that enables them to position themselves so that maximum light reaches their chloroplasts
Euglena is a single-celled eukaryote that makes use of autotrophic and heterotrophic nutrition
Plant & Algal Nutrition
NOS: Looking for patterns, trends and discrepancies; plants and algae are mostly autotrophic but some are not
The majority of plants and algae are photosynthetic, meaning that they are autotrophs that rely on energy from the sun to convert carbon dioxide in the air into organic molecules in their tissues
Their photosynthetic cells contain pigments which absorb light energy
The main pigment in green plants is chlorophyll, which primarily absorbs light at the red and blue ends of the visible spectrum, reflecting green light
Green plants also have carotenoid pigments, known as accessory pigments, which extend the range of light wavelengths that can be absorbed; these pigments appear to be red, yellow, or purple and remain in mature leaves after chlorophyll degrades
Brown algae, such as the seaweed kelp, contain a brown pigment called fucoxanthin
Red algae and green algae have pigments called phycobilins
There are some unusualexceptions to the autotrophic mode of nutrition used by most plants and algae
Some plants parasitise the roots of other plants, tapping into the roots of these plants to gain their organic molecules
E.g. groundcone plants look like upright pine cones sitting on the ground, but are in fact parasitic plants, having no photosynthetic pigments of their own, and gaining their organic molecules from the roots of surrounding trees
Some plants parasitise fungi, a feeding mode known as mycoheterotrophy, gaining their organic molecules from the network of fungal cells in the soil
The rare plant Epipogium aphyllum, also known as the ghost orchid, has no leaves and no chlorophyll, gaining its organic molecules from the fungi that form associations with tree roots
When exceptions to accepted trends are observed in the natural world, it can sometimes mean that established modes of thinking are incorrect, so it is important to consider discrepancies carefully
In the case of non-photosynthetic plants and algae:
They are rare
They appear to have evolved on multiple occasions from autotrophic ancestors
There is not enough evidence to disprove the mode of thinking that says that plants and algae are autotrophs, but we can say that there are a few exceptions to this rule
Types of Heterotrophic Nutrition
There are several ways in which heterotrophs gain organic molecules from other organisms
Consumers
Consumers gain their organic molecules by ingesting the tissues of other living organisms or recently dead organisms
The consumers that eat plants are known as herbivores, and the consumers that eat other animals are known as carnivores
Detritivores
Detritivores gain organic molecules by ingesting the tissues of dead organisms or ingesting animal waste
Detritivores carry out internal digestion, meaning that they digest their food inside their bodies
Examples of detritivores include earthworms, woodlice and dung beetles
Saprotrophs
Saprotrophs also ingest the tissues of dead organisms and waste material, but they secrete enzymes onto their food, and digest it externally
The products of this external digestion are then absorbed
Examples of saprotrophs include fungi and bacteria
Saprotrophs secrete a wide range of digestive enzymes that allow them to hydrolyse (break down) a large variety of biological molecules, releasing a large range of products as a result
Examples of these products include mineral ions, such as ammonium ions and phosphateions
Importantly, not all of the products of external digestion get absorbed by saprotrophs
Instead, some of the products remain in the surrounding soil and become available to other organisms such as plants
This is why saprotrophs are such an essential component of ecosystems and food webs
Without them, the nutrients locked up in dead and waste matter would never be made available again and producers such as plants would not have access to sufficient nutrients