Matrix (biology)

About: Matrix (biology) is a research topic. Over the lifetime, 3733 publications have been published within this topic receiving 180288 citations. The topic is also known as: extracellular matrix & bone extracellular matrix.

The biofilm matrix

Abstract: The extracellular matrix is a complex and extremely important component of all biofilms, providing architectural structure and mechanical stability to the attached population. The matrix is composed of cells, water and secreted/released extracellular macromolecules. In addition, a range of enzymic and regulatory activities can be found within the matrix. Together, these different components and activities are likely to interact and in so doing create a series of local environments within the matrix which co-exist as a functional consortium. The matrix architecture is also subject to a number of extrinsic factors, including fluctuations in nutrient and gaseous levels and fluid shear. Together, these intrinsic and extrinsic factors combine to produce a dynamic, heterogeneous microenvironment for the attached and enveloped cells.

Hyaluronan: its nature, distribution, functions and turnover

Abstract: Hyaluronan is a polysaccharide found in all tissues and body fluids of vertebrates as well as in some bacteria. It is a linear polymer of exceptional molecular weight, especially abundant in loose connective tissue. Hyaluronan is synthesized in the cellular plasma membrane. It exists as a pool associated with the cell surface, another bound to other matrix components, and a largely mobile pool. A number of proteins, the hyaladherins, specifically recognize the hyaluronan structure. Interactions of this kind bind hyaluronan with proteoglycans to stabilize the structure of the matrix, and with cell surfaces to modify cell behaviour. Because of the striking physicochemical properties of hyaluronan solutions, various physiological functions have been assigned to it, including lubrication, water homeostasis, filtering effects and regulation of plasma protein distribution. In animals and man, the half-life of hyaluronan in tissues ranges from less than 1 to several days. It is catabolized by receptor-mediated endocytosis and lysosomal degradation either locally or after transport by lymph to lymph nodes which degrade much of it. The remainder enters the general circulation and is removed from blood, with a half-life of 2-5 min, mainly by the endothelial cells of the liver sinuoids.

Cell Biology of Extracellular Matrix

Abstract: Introductory Remarks.- I. What Is Extracellular Matrix?.- 1 Collagen.- 2 Proteoglycans: Structure and Function.- 3 The Elastic Fiber.- 4 Fibronectin and Other Cell Interactive Glycoproteins.- II. How Do Cells Produce the Matrix?.- 5 Proteoglycans: Metabolism and Pathology.- 6 Collagen Biosynthesis.- 7 Matrix Assembly.- 8 Extracellular Matrix Degradation.- III. What Does Matrix Do for Cells?.- 9 Proteoglycans and Hyaluronan in Morphogenesis and Differentiation.- 10 Integrins as Receptors for Extracellular Matrix.- 11 The Glomerular Basement Membrane: A Selective Macromolecular Filter.- 12 Collagen and Other Matrix Glycoproteins in Embryogenesis.

In vitro differentiation and calcification in a new clonal osteogenic cell line derived from newborn mouse calvaria

Abstract: We investigated the capacity of a clonal osteogenic cell line MC3T3-E1, established from newborn mouse calvaria and selected on the basis of high alkaline phosphatase (ALP) activity in the confluent state, to differentiate into osteoblasts and mineralize in vitro. The cells in the growing state showed a fibroblastic morphology and grew to form multiple layers. On day 21, clusters of cells exhibiting typical osteoblastic morphology were found in osmiophilic nodular regions. Such nodules increased in number and size with incubation time and became easily identifiable with the naked eye by day 40-50. In the central part of well-developed nodules, osteocytes were embedded in heavily mineralized bone matrix. Osteoblasts were arranged at the periphery of the bone spicules and were surrounded by lysosome-rich cells and a fibroblastic cell layer. Numerous matrix vesicles were scattered around the osteoblasts and young osteocytes. Matrix vesicles and plasma membranes of osteoblasts, young osteocytes, and lysosome-rich cells showed strong reaction to cytochemical stainings for ALP activity and calcium ions. Minerals were initially localized in the matrix vesicles and then deposited on well-banded collagen fibrils. Deposited minerals consisted exclusively of calcium and phosphorus, and some of the crystals had matured into hydroxyapatite crystals. These results indicate that MC3T3-E1 cells have the capacity to differentiate into osteoblasts and osteocytes and to form calcified bone tissue in vitro.