Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UNIPROT:P20645 (mannose-6-phosphate receptor)
 320 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Bone resorption plays an important role in bone modeling and remodeling. Osteoclasts are the cells responsible for the bone resorption. Osteoclasts are located on endosteal bone surfaces and on the periosteal surface beneath the periosteum. They are multinucleated giant cells highly polarized in their morphology and function. Among the proximal surface, the membrane and the area of the cytoplasm directly oppose to the bone surface, which are specialized into two regions. A central region consisting of many irregular cytoplasmic processes and infoldings, the ruffled border, is known to be the active site of bone resorption. Surrounding the ruffled border, a second region, the clear zone provides an area of close attachment to the mineralized bone surface. The osteoclasts secrete a large amount of protons by the action of H(+)-pump on the ruffled border into the sealed resorption cavity, resulting in the acidified microenvironment under which condition the bone matrix is dissolved. Protons are provided by the intracellular action of carbonic anhydrase. Following the secretion of the protons, several ion-transporting systems, i.e., carbonate-chloride exchanger, chloride-channel, Ca(2+)-transport systems, Na+/K(+)-ATPase, and voltage-dependent Ca(2+)-channel, are sequentially operated on both apical and basolateral cytoplasmic membranes. In addition, osteoclasts contain a large amount of lysosomal enzymes (cathepsin C, beta-glycerophosphatase, beta-glucuronidase, etc.), which contribute to degrade the bone organic matrices exposed in the resorption cavity. These enzymes bind to the mannose-6-phosphate receptor on Golgi apparatus, are transported to the ruffled border and are secreted into the extracellular compartment in an exocytotic manner. Osteoclasts also have a high tartrate-resistant acid phosphatase activity which is currently used as a marker enzyme osteoclastic differentiation. Osteoclasts are considered to develop from hematopoietic stem cells. So far, the following four different pathways of the differentiation of osteoclast are proposed: The precursors of osteoclast develop (1) from multilineage hematopoietic cells via a completely separate differentiation line, (2) from granulocyte macrophage-colony forming cells, (3) from committed but proliferative monocyte-macrophage, and (4) from mature and unproliferative monocyte-macrophage. However, the differentiation line of the osteoclasts has still to be elucidated. The formation of osteoclasts as well as that of other hematopoietic cells is strongly regulated by many cytokines [interleukin (IL)-1,IL-3,IL-6, M-colony stimulating factor (CSF), and GM-CSF]. 1,25-Dihydroxyvitamin D3 and parathyroid hormone also stimulate the differentiation of osteoclast precursors. However, the mature osteoclasts do not possess the receptors for these hormones.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:[Osteoclasts in bone metabolism]. 175 56

Osteoclasts develop from precursor cells of the monocyte series. However, specialized differentiation for efficient bone degradation separates the osteoclast from the macrophage. The physical reasons for these differences are emerging from the study of osteoclastic physiology and biochemistry. Key osteoclast specializations are multinucleation, formation of a tightly sealed extracellular compartment on bone, and high-capacity secretion of HCl and acid proteases into this extracellular site. Multinucleation increases efficiency of extracellular attachment processes. The attachment process is mediated by cell membrane integrins, and is sensitive to changes in intracellular or extracellular calcium. Acid production exploits carbonic acid as the source of acid and conjugate base equivalents, reflected in abundant osteoclastic carbonic anhydrase type II expression. Secretion of acid involves extremely high expression of vacuolar-type H(+)-ATPase and a chloride channel in the cell's specialized acid secreting organelle, the ruffled membrane, which is polarized to the osteoclast's bone attachment. Acid secretion is balanced by chloride-bicarbonate exchange in the cell's nonbone attached membranes; this functionally resembles the band 3 chloride-bicarbonate exchanger of the red cell carbon dioxide transport system. Bone collagen is degraded by acid proteases secreted into the acid degradation site via the mannose-6-phosphate receptor system, which is targeted to lysosomes in other cells. Functional deficits, as in osteopetrosis, may affect any of the elements involved in osteoclast differentiation. Furthermore, new antiosteoclastic therapeutic agents may inhibit osteoclast biochemistry intentionally, such as for the control of hypercalcemia of malignancy.
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PMID:Recent advances toward understanding osteoclast physiology. 839 72

The term 'protein-specific glycosylation' refers to important functional implications of a subset of glycosylation types that are under direct control of recognition determinants on the protein. Examples of the latter are found in the formation of the mannose-6-phosphate receptor ligand on lysosomal hydrolases, and in polysialylation of NCAM, which are regulated via conformational signal patches on the protein. Distinct from these examples, the beta4-GalNAc modification of N-linked glycans on a selected panel of proteins, such as carbonic anhydrase or glycodelin, was demonstrated recently to require specific protein (sequence) determinants proximal to the glycosylation site that function as cis-regulatory elements. Another example of such a cis-regulatory element was described for the control of mammalian O-mannosylation. In this case, the structural features of substrate sites within the mucin domain of alpha-dystroglycan are necessary, but not sufficient for determining the transfer of mannose to Ser/Thr. Evidence has been provided that an upstream-located peptide is also essential. Such cis-controlling elements provide a higher level of protein specificity, because a putative glycosylation site cannot result from a single point mutation. Here, we highlight recent work on protein-specific glycosylation with particular emphasis on the above-cited examples and we will try to link protein-specific glycosylation to function.
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PMID:Protein-specific glycosylation: signal patches and cis-controlling peptidic elements. 1928 92