Skin and Mucosal Membranes
The skin and mucosal membranes of the human body are not simply inert physical barriers that keep good things in and bad things out. They comprise the body’s largest organ, which has a complex array of activities and functions that are only now beginning to be fully appreciated. As humans and other life-forms evolved, they were forced to contend in a bacteria-dominated world in which bacteria tended to view them as a free lunch. Survival meant developing defenses to keep these bacteria at bay. As such, these fortress-like defenses are extremely effective against bacterial incursions, preventing most bacteria from entering human tissues and the bloodstream and instead relegating them to the surface of the skin or confining them to certain closely guarded mucosal areas of the human body, such as the oronasopharyngeal (mouth, nose, and pharynx/throat), gastrointestinal, and urogenital tracts. Fortunately for us, only a tiny minority of bacteria is able to bypass these defenses and cause disease. To understand the mechanisms by which pathogenic bacteria cause disease, it is first essential to know what obstacles those few bacteria that do cause disease must overcome.
The Layers of Cells That Protect the Body
Epithelia are the layers of cells covering all of the external and internal surfaces of the body that are exposed to the external environment. These epithelial cell layers are an important initial defense against potential pathogens. The epithelial cells found in different body sites differ considerably in their properties, but they have some features in common.
Skin consists of a lining of living cells composed of two layers, the epidermis (outer layer) and the dermis (inner layer) (Figure 2-1). Cells of the dermis are continuously replaced as they die and become a tough, dry outer layer called the epidermis. The epithelia that line the respiratory, intestinal, and urogenital tracts are the mucosal epithelia and consist of tightly packed cells that are attached to each other by protein structures called tight adherens junctions and desmosomes (Figure 2-2). The tight binding of epithelial cells to each other prevents bacteria from transiting an epithelial layer. To get through the epithelial layer, bacteria must either take advantage of wounds or be capable of invading epithelial cells, passing between or through them to get to the underlying tissue.
Figure 2-1. Structure of the skin. The thick epidermis (outer layer, top) consists of keratinized, stratified squamous cells, the top layers of which are dead and continuously shed. When these cells are sloughed, they carry adhering bacteria with them. The inner layer is the dermis (middle). Sebaceous (fat) glands, sweat glands, and hair follicles, which produce antibacterial substances, provide openings in the skin through which pathogenic bacteria occasionally enter. The skin also has an adaptive defense system, the skin-associated lymphoid tissue (SALT). Langerhans cells serve as phagocytic cells in this system.
Figure 2-2. Intestinal epithelial cells showing tight, junctional, and adherens junctions, and desmosomes. JAM, junctional adhesion molecules.
In contrast, the cells that line the surfaces of the interior of the body (the endothelium), such as blood vessels or lymphatic vessels, are not tightly bound to each other in order to allow the cells of the immune defense system to move freely from blood to tissues. Unfortunately, this feature also allows bacteria to move into and out of blood and lymphatic vessels by moving between the endothelial cells. Thus, once bacteria gain entry into the body at one site, it is possible for them to readily gain access to other parts of the body. Because of this vulnerability, it is imperative that the epithelia of skin and mucosal surfaces function as barriers against foreign invaders.
The membrane surface of an epithelial cell that faces toward the interior tissues of the body and is attached to other cells or to connective tissues (basolateral surface) has a different protein composition from the membrane surface that faces outward (apical surface). Cells with this asymmetrical surface property are said to be polarized cells. A feature of epithelial cells is that they are attached to a thin sheet of connective tissue called the basement membrane (basal lamina). The basal lamina covers regions of loose connective tissue (Figure 2-3), comprised of extracellular matrix (ECM) secreted by elongated fibroblast cells. The ECM composition varies with tissue type, but primarily contains a network of interlocking gels of polysaccharides called glycosaminoglycans (such as chondroitin sulfate, hyaluronan, keratan sulfate, and heparan sulfate) attached to fibrous collagens, the most abundant protein type in the ECM. Collagens bind to adhesion glycoproteins called fibronectins, which in turn bind collagens to transmembrane cell surface proteins called integrins that mediate cell-cell and cell-ECM interactions and cytoskeletal responses. Other ECM proteins called laminins bind to collagens and other ECM components to form fibrous networks that resist tensile forces in the basal lamina. There are numerous examples of pathogenic bacteria that attach to components of the ECM and manipulate or mimic ECM components during the course of infection.
Figure 2-3. Different types of epithelial cells and their relationships to underlying tissue. Shown are (A) simple squamous epithelium; (B) simple cuboidal epithelium; (C) stratified squamous epithelium (upper layers of cells are dead, typical of skin); (D) simple columnar epithelium; (E) ciliated columnar epithelium showing goblet cells, which secrete mucus (mucin); and (F) typical structure of connective tissue under an epithelial cell layer. Panel F modified from Cooper GM, Hausman RE. 2007. The Cell—A Molecular Approach, 4th ed. ASM Press, Washington, DC.
Epithelial cells in different body sites vary in shape, size, and number of layers (Figure 2-3), as well as in functional properties. Epithelial layers that cover surfaces where absorption or secretion is taking place (e.g., in the intestinal tract) usually consist of a single layer of epithelial cells (simple epithelium). Other surfaces, such as the female cervix or the skin, are composed of many layers of epithelial cells (stratified epithelium). Some have a flattened shape (squamous epithelium) and form the lining of cavities (such as the mouth, heart, and lungs) and the outer layers of the skin. Some are cube-shaped (cuboidal epithelium) and form the lining of kidney tubules and gland ducts and constitute the germinal epithelium that develops into egg and sperm cells. Others are tall and thin (columnar epithelium) and form the lining of the stomach and intestine.
Most of the surfaces that are exposed directly to the environment (e.g., the skin and mouth) are covered by stratified epithelia, whereas simple epithelia are found in internal areas, such as the intestinal tract or the lungs. Simple epithelia are more vulnerable to bacterial invasion than stratified epithelia because invading bacteria only have to pass through one layer of cells to gain access to the tissue underneath. We will use the terms mucosa epithelia, epithelial cells, mucosal layer, or mucosal cells to denote the simple epithelia of these internal areas.
Epithelia are protected by an array of innate and adaptive defenses. Some of these defenses are listed in Table 2-1 for the skin and Table 2-2 for mucosal surfaces. Other defenses, listed in Table 2-3, are more specific to certain areas of the body, such as the eyes and the respiratory, gastrointestinal, and urogenital tracts. For example, tears contain an enzyme (lysozyme) that degrades bacterial cell walls. Tears also provide a washing action that removes particles and bacteria from the eyes. Entry to the respiratory tract is protected by mucus and by specialized ciliated cells that propel bacteria-laden blobs of mucus out of the lungs. The urinary tract epithelium is protected by a sphincter at the end of the urethra, the tube that leads up to the bladder. This barrier makes it difficult for bacteria to enter the tube that leads to the bladder. Also, the