Physiology, Connective Tissue

Article Author:
Trevor Nezwek
Article Editor:
Steven Lasser
Updated:
6/4/2019 11:53:13 AM
PubMed Link:
Physiology, Connective Tissue

Introduction

Connective tissue is the most abundant and diverse type of animal tissue. Animal tissue divides into four basic groups, which include epithelial tissue, muscle tissue, nervous tissue, and connective tissue. Similar to a framework of a house, connective tissue serves to provide structure, support, and protection throughout the human body.[1]

Cellular

Connective tissue is an umbrella that encompasses a variety of tissue types, including loose and dense connective tissue, adipose, cartilage, bone, and blood. Although connective tissue is diverse, all connective tissue consists of three main components: 

  1. Ground substance
  2. Fibers
  3. Cells

Together, the ground substance and fibers make up the extracellular matrix, which is the structural support of surrounding cells throughout the body. The composition of the extracellular matrix varies tremendously from organ to organ, which allows for the diverse types of connective tissue.[2]

Ground substance is an amorphous gelatinous material with a high water content that is found occupying the space between cells and fibers. It is composed of glycosaminoglycans, particularly hyaluronic acid, proteoglycans, and cell adhesion proteins, such as laminin and fibronectin, to act as a glue for cells in the extracellular matrix. The purpose of the ground substance is to allow for the exchange of cellular nutrients between cells and capillaries.[3]

Fibers are another main component of connective tissue found in the extracellular matrix. There are three basic fiber types that are present in all connective tissue. The amount of each type generally reflects the function and classification of the particular tissue. The three fiber types are:

  • Collagenous fibers: large, strong fibers, mostly commonly Type I collagen, that provides high tensile strength to the extracellular matrix, found in dense and loose connective tissue.[1]
  • Reticular fibers: delicate, thin fibers composed of Type III collagen that cross-link to form a supporting meshwork in the reticular lamina of the basement membrane found in soft tissues such as the liver, bone marrow, spleen, and lymph nodes.[4]
  • Elastic fibers: thin, branching fibers made of elastin that provide stretch and recoil to the extracellular matrix, found in tissues such as aorta, lung, skin, and vocal cords.[5]

To further understand the physiology of connective tissue, it is important to note the different types of collagen, which are generally composed of fibers found in the extracellular matrix. Collagen is the most abundant protein found in the human body and has 28 types.[6] The four most common types are:

  • Type I: the most common type; flexible, strong, provides resistance to force, tension, and stretch; found in all connective tissue, notably scar tissue, tendons, ligaments, bone, cornea, skin, and dentin.
  • Type II: provides resistance to pressure, found in articular and hyaline cartilage of joints and intervertebral discs.
  • Type III: provides a flexible meshwork for cellular support; the main component of reticular fibers, often found in organs such as skin and blood vessels. Also abundant during the early stages of wound healing and plays a role in granulation tissue formation.[7]
  • Type IV: meshwork that provides support and attachment to the underlying extracellular matrix forms the basal lamina of the basement membrane; an important component of the kidneys, inner ear, and lens of the eye.

Commons cells of the connective tissue consisting of fibroblasts, macrophages, adipocytes, leukocytes, and mast cells.[8]

Collagen Synthesis and Structure

The synthesis of collagen begins with DNA translation of a polypeptide chain in the rough endoplasmic reticulum of intracellular space. This polypeptide chain is known as preprocollagen, composed of alpha chains with repeating amino acid glycine-X-Y sequences (X and Y are proline or lysine).[9]

The proline and lysine residues of the alpha chain then become hydroxylated with the help of vitamin C dependent hydroxylases; hydroxylation helps form a stable structure. Vitamin C deficiency results in impaired hydroxylation of preprocollagen and defective collagen synthesis, a condition known as scurvy.[10]

Next, the hydroxylated lysine of the alpha chain undergoes glycosylation with the addition of a carbohydrate. After glycosylation, the formation of disulfide bonds and hydrogen bonds between three different alpha chains forms a triple helix. The resultant structure is now procollagen. Defective triple helix formation leads to the condition of osteogenesis imperfecta and impaired bone matrix synthesis.[11] 

Procollagen then shuttles to the extracellular space through exocytosis. Once in the extracellular space, procollagen is cleaved at the C-terminus and N-terminus forming what is now called tropocollagen. Tropocollagen is insoluble in water as a result of the cleavage.

Next, tropocollagen is reinforced with many adjacent tropocollagen molecules by covalent cross-linking of hydroxylated lysine residues, resulting in collagen fibrils. The cross-linking of hydroxylysine residues is made possible through a copper-dependent lysyl oxidase enzyme.

Finally, several of these collagen fibrils accumulate to form a thick bundle, which is the end product referred to as collagen fibers.[12]

Development

Connective tissue largely derives from mesenchyme which originates from the mesoderm. However, some bones of the face and skull also have contributions from neural crest cells, which originate from ectoderm.[13]

Function

Connective tissue has a variety of different functions depending on its classification.[14] In summary, connective tissue provides:

  1. Resistance to stretch and tear
  2. Structural support
  3. Insulation
  4. Storage of body fuels
  5. A medium for intercellular exchange

Clinical Significance

There are over 200 documented disorders of connective tissue.[15] The etiology can include autoimmune diseases, genetic disorders, or cancers. One of the more common autoimmune connective tissue disorders is rheumatoid arthritis. Rheumatoid arthritis is a chronic inflammatory disorder characterized by autoimmune destruction and deterioration of cartilage and bone. It classically presents in middle-aged women with symmetrical pain and swelling of the metacarpophalangeal joints and proximal interphalangeal joints with sparing of the distal interphalangeal joints. It can also manifest as low-grade fevers, myalgias, malaise, night sweats and can affect a variety of organs throughout the body.[16]

A rare yet interesting inherited connective tissue disorder is osteogenesis imperfecta, also known as brittle bone disease. It results from an autosomal dominant mutation leading to defective type I collagen synthesis and impaired bone matrix formation. It can present as recurrent fractures (notably long bones or ribs) with minimal trauma in children, which often gets mistaken as child abuse. Some other manifestations include blue sclerae, progressive hearing loss, and brittle, opalescent teeth.[17] Another example of an inherited connective tissue disease is Alport syndrome. Alport syndrome is commonly an X-linked dominant disorder resulting in a genetic defect in type IV collagen, which leads to a characteristic splitting of the glomerular basement membrane most notably in the kidneys. This condition usually presents in boys with glomerulonephritis, sensorineural deafness, and ocular abnormalities such as retinopathy and lens dislocation.[18]

One fascinating area of research that can make a significant impact in the field of orthopedics is the concept of tissue engineering. Biomedical engineers and orthopedic surgeons are working together to create novel strategies to repair and regenerate damaged tissues. For example, there is research being done at the University of Pennsylvania using animal meniscus as a model system to study an engineered implantable platform that would serve for wound healing. The meniscus, being composed of dense connective tissue, is generally too dense to allow stem cells to move to the site of injury and start the repair process. Researchers at Penn have developed a microscopic scaffold that is laced with an enzyme to loosen the matrix in addition to growth factors that attract stem cells. When the researchers placed this microscopic scaffold in damaged meniscus tissue from a cow, the matrix loosened and allowed for bone stem cells to travel to the scaffold and start the repair process. The next phase of research intends to look at large animal models and eventually, human trials.[19]



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