28.1 Complex multicellularity arose several times in evolution.
Bacteria are unicellular or form simple multicellular structures. page 578
Eukaryotes are unicellular or multicellular and exhibit both simple and complex multicellularity. page 578
Simple multicellularity involves the adhesion of cells with little cell differentiation. Complex multicellularity involves cell adhesion, cell signaling, and differentiation and specialization among cells. page 578
Complex multicellular organisms have evolved independently at least six times: in animals, vascular plants, red algae, brown algae (the kelps), and at least twice in the fungi page 580
28.2 In complex multicellular organisms, bulk flow circumvents the limitations of diffusion.
Diffusion is the random motion of molecules, with net movement occurring from regions of higher to regions of lower concentration. It generally acts over small distances, placing limits on the size of multicellular organisms. page 581
Bulk flow is an active process that allows multicellular organisms to nourish cells located far from the external environment, thereby circumventing the constraints imposed by diffusion. page 582
28.3 Complex multicellularity depends on cell adhesion, communication, and a genetic program for development.
Animal and plant cells are organized into tissues characterized by specific molecular attachments between cells. page 583
594
Choanoflagellates express some of the same proteins that permit cell adhesion in animals, even though choanoflagellates are unicellular. Experiments suggest that choanoflagellates use these proteins to capture bacteria, not for cell adhesion. page 583
Gap junctions in animals and plasmodesmata in plants allow cells to communicate with each other in a targeted fashion. page 585
The cells of complex multicellular organisms are genetically programmed to differentiate into multiple cell types in space. page 586
A number of gene families known to play developmental roles in multicellular organisms are also present in their unicellular relatives, where at least some of them play a role in life cycle differentiation. page 587
28.4 Plants and animals evolved complex multicellularity independently of each other and solved similar problems with different sets of genes.
The cell wall characteristic of plant cells provides structural and mechanical support, but does not allow plant cells to move. page 587
The cell wall of plants has led to distinct solutions to the problems of cell adhesion, cell communication, and development. For example, plants grow by the activity of meristems, populations of actively dividing cells at the tips of stems and roots. page 587
Animal cells do not have cell walls, allowing cell movement that is not possible in plants. For example, during animal development, cells of the embryo migrate inward to form a layered structure called a gastrula. page 588
28.5 The evolution of large and complex multicellular organisms, which required abundant oxygen, is recorded by fossils.
Oxygen may be required for the evolution of complex multicellularity because of its chemical properties and its abundance. page 590
The evolution of complex multicellularity observed in the fossil record correlates with increases in atmospheric oxygen that occurred 580–
Complex multicellular organisms evolved later on land, as ancestral plants evolved the capacity to photosynthesize surrounded by air rather than water. page 591
Evolutionary-
Describe differences between simple and complex multicellularity.
In simple multicellularity, adhesive molecules cause adjacent cells to stick together, but there is relatively little communication or transfer of resources between cells. There is also little differentiation of cell types; most of the cells in simple multicellular organisms retain a full range of functions. In simple multicellular organisms, every cell is in direct contact with the external environment during phases of the life cycle when the cells must acquire nutrients. Complex multicellularity, like simple multicellularity, also involves adhesion, but the mechanisms for adhesion are highly developed. Unlike simple multicellular organisms, however, complex multicellular organisms differentiate different cell types, tissues, and organs. Cells in complex multicellular organisms communicate with each other through signaling mechanisms that allow coordinated growth and cell differentiation. Complex multicellular organisms employ bulk flow to distribute nutrients, rather than relying on diffusion, allowing the organisms to grow to a greater size.
Describe the phylogenetic distribution of complex multicellularity.
Complex multicellularity is found in three of the seven eukaryotic superkingdoms, and is thought to have evolved independently at least six times.
Explain how diffusion limits the size of organisms.
Diffusion—
Explain how multicellular organisms get around the size limits imposed by diffusion.
Plants and animals get around the size limits imposed by diffusion by actively pumping nutrients and other molecules to all parts of the organism through bulk flow. Other organisms, like sponges or jellyfish, grow large by adopting shapes and structures that allow metabolically active cells to remain in close proximity to the environment.
Describe a key difference between multicellular plants and animals.
One key difference is that plants have cell walls around their cells, whereas animals do not. Cell walls restrict the plant cells from moving, in this way determining many features of development and function.
Describe environmental changes recorded by the sedimentary rocks that contain the oldest fossils of large active animals.
The study of sedimentary rocks shows that abundant oxygen came to exist about 580‒560 million years ago. This corresponds in time to the first fossil records of complex multicellular organisms.