Cell Biology: Cell Structure and Function PDF

Summary

This document provides a comprehensive overview of cell biology, focusing on cell structure, types of cells, and cellular processes. It covers eukaryotic and prokaryotic cells, differentiation, and membrane transport mechanisms.

Full Transcript

Cell is the basic unit of life, the smallest living part of the body

In all tissues, cells themselves are the basic structural and functional
units

Types of Cell


- Prokaryotic

- Eukaryotic

Eukaryotic cells


Animal cells with distinct membrane-limited nuclei surrounded by
cytoplasm containing various organelles and the cytoskeleton

- Prokaryotic cells


Bacterial cells that typically have a cell wall around the plasmalemma
and lack nuclei and membranous cytoplasmic structures

- The human organism consists of hundreds of different cell types all
derived from the zygote

- The zygote is formed by the merger of a spermatozoon with an oocyte
at fertilization

- The first zygotic cellular divisions produce cells called
blastomeres

- Blastomeres give rise to all tissue types of the fetus

- Embryonic stem cells


Cells of the inner cell mass explanted to tissue culture

- Most cells of the fetus undergo a specialization process called
differentiation

- Differentiation involves differential expression of sets of genes
that mediate specific cytoplasmic activities

- Muscle cell precursors elongate into fiber-like cells containing
large arrays of actin and myosin

- All animal cells contain actin filaments and myosin

- Specialized cells


Have greatly expanded their capacity for one or more functions during
differentiation

- Changes in cells' microenvironments can cause the same cell type to
have variable features and activities

- Cells that appear similar structurally often have different families
of receptors for signaling molecules

- The cell membrane functions as a selective barrier regulating the
passage of materials into and out of the cell

- The cell membrane facilitates the transport of specific molecules

- One important role of the cell membrane is to keep constant the ion
content of cytoplasm

- Membranes carry out specific recognition and signaling functions

- Certain plasma membrane proteins, the integrins, are linked to both
the cytoskeleton and ECM components

- Membranes range in thickness and are visible only in the electron
microscope

- Phospholipids


Amphipathic molecules consisting of two nonpolar long-chain fatty acids
linked to a charged polar head

- Phospholipids are most stable when organized into a double layer
(bilayer)

- Some of the outer layer's lipids are known as glycolipids

- Glycolipids include oligosaccharide chains that contribute to a
delicate cell surface coating called the glycocalyx

- Proteins are major constituents of membranes (\~50% by weight in the
plasma membrane)

- Integral proteins


Incorporated directly within the lipid bilayer

- Peripheral proteins


Bound to one of the two membrane surfaces, particularly on the
cytoplasmic side

- Fluid mosaic model


Membrane proteins are not bound rigidly in place and can move laterally

- The plasma membrane is the site where materials are exchanged
between the cell and its environment

- Mechanisms for small molecules crossing the membrane

- Diffusion

- Channels

- Carriers

- Diffusion


Transports small, nonpolar molecules directly through the lipid bilayer

- Lipophilic molecules diffuse through membranes readily, water very
slowly

- Channels


Multi-pass proteins forming transmembrane pores for selective passage of
ions or small molecules

- Cells open and close specific channels for Na+, K+, Ca2+ and other
ions in response to various physiological stimuli

- Water molecules usually cross the plasma membrane through channel
proteins called aquaporins

- Carriers


Transmembrane proteins that bind small molecules and translocate them
across the membrane

- Passive Transportation


1\. Diffusion

2\. Channels

3\. Carrier proteins operate passively

- Passive transport allows movement of substances across membranes
down a concentration gradient

- Types of Passive Transportation

- Simple Diffusion

- Facilitated Diffusion

- Osmosis

- Osmosis is the diffusion of water across a selectively permeable
membrane

- Active Transport


Membrane pumps utilize energy from ATP to move ions and solutes across
membranes

- Membrane pumps are often referred to as ATPases

- Vesicular Transport


1\. Endocytosis

2\. Exocytosis

- Macromolecules enter cells by being enclosed within folds of plasma
membrane in a process known as endocytosis

- Types of Endocytosis


- Phagocytosis

- Pinocytosis

- Receptor-mediated endocytosis

- Phagocytosis


The ingestion of particles such as bacteria or dead cell remnants

- Macrophages and neutrophils are specialized for phagocytosis

- When a bacterium binds to the surface of a neutrophil, it becomes
surrounded by extensions of plasmalemma and cytoplasm

- Fusion of the membranous folds encloses the bacterium in an
intracellular vacuole called a phagosome

- The phagosome merges with a lysosome for degradation of its contents

- Pinocytosis


Involves smaller invaginations of the cell membrane that entrap
extracellular fluid and its dissolved contents

- The resulting pinocytotic vesicles then pinch off inwardly from the
cell surface

- Pinocytotic vesicles either fuse with lysosomes or move to the
opposite cell surface

- Phagocytosis


Process where a bacterium is engulfed by a cell

- Phagocytosis


1\. Bacterium binds to neutrophil

2\. Extensions of plasmalemma surround bacterium

3\. Fusion encloses bacterium in phagosome

4\. Phagosome merges with lysosome

- Pinocytosis


Involves smaller invaginations of the cell membrane that entrap
extracellular fluid

- Pinocytosis


1\. Invagination of cell membrane

2\. Formation of pinocytotic vesicles

3\. Vesicles pinch off from cell surface

4\. Vesicles fuse with lysosomes or release contents

- Receptor-mediated Endocytosis


Involves receptors binding specific molecules (ligands)

- Receptor-mediated Endocytosis


1\. Receptors bind ligands

2\. Receptors aggregate in membrane region

3\. Membrane invaginates and pinches off

4\. Creates vesicle or endosome

- Exocytosis


Movement of large molecules from inside to outside the cell

- Exocytosis


1\. Vesicle containing molecules fuses with plasma membrane

2\. Release of contents into extracellular space

- Membrane trafficking


Process of membrane movement and recycling during endocytosis and
exocytosis

- Signal Reception & Transduction


Cells communicate to regulate development, growth, and function

- Gap junctions


Allow exchange of ions and small molecules between adjacent cells

- Types of signaling


- Endocrine signaling

- Paracrine signaling

- Synaptic signaling

- Autocrine signaling

- Juxtacrine signaling

- Synaptic signaling


Neurotransmitters act on adjacent cells through synapses

- Endocrine signaling


Hormones are carried in the blood to target cells

- Paracrine signaling


Chemical ligand diffuses in extracellular fluid for local effect

- Autocrine signaling


Signals bind receptors on the same cells that produced them

- Juxtacrine signaling


Signaling molecules are cell membrane-bound proteins that bind surface
receptors upon direct contact

- Plasma Membrane


Phospholipid bilayer forming a selectively permeable boundary

- Cilia


Short, numerous membrane extensions supported by microtubules

- Flagellum


Long, singular membrane extension supported by microtubules

- Microvilli


Thin membrane folds projecting from the free cell surface

- Nucleus


Large structure containing chromatin, nucleolus, and nucleoplasm

- Nuclear Envelope


Double membrane boundary between cytoplasm and nuclear contents

- Nuclear pores


Openings through the nuclear envelope

- Nucleolus


Large, prominent structure within the nucleus

- Cytoplasm


Contents of cells between the plasma membrane and nuclear envelope