破骨細胞
破骨細胞 (英語:osteoclast )又称蝕骨細胞 [ 1] 骨 組織中的細胞,由多個單核細胞 融合而成,直徑最大可達100微米,細胞核 的數目一般是6-50個[ 2] [ 3] 乳酸 、檸檬酸 、碳酸 、碳酸酐酶及溶酶體酶等,對骨組織進行分解破壞[ 2] [ 4] [ 5] [ 6]
破骨細胞於1873年由德國的阿尔伯特·冯·科立克 最早發現[ 7] 古希臘語 ὀστέον (osteon),意爲骨;-clast 來自古希臘語 κλαστός (clastos),意爲破壞。
在牙發育過程中,能吸收脫落乳牙 牙根的破牙本質細胞與破骨細胞相似,兩者存在一定的聯繫[ 8] [ 9] [ 10]
對抗酒石酸酸性磷酸酶 已活化的破骨細胞的圖示橫截面 破骨細胞是起源於骨髓單核細胞的多核巨細胞 [ 11] [ 12] 細胞核 ,直徑為150-200µm。當使用趨化因子 將巨噬細胞轉化為破骨細胞時,可能會出現直徑達到100µm的極大細胞,具有數十個細胞核,並且通常會表達主要的破骨細胞蛋白。由於不是天然的底物,因此與活骨中的細胞有顯著差異[ 13] [ 14] 巨噬細胞 的離子 轉運,同時蛋白質分泌和囊泡轉運能力集中在骨頭的局部區域。
有研究發現,骨吸收能力是由破骨細胞數量及單個細胞降解骨基質的能力所決定[ 15] 基質 接觸,通過整合素αVβ3 溶酶體 酶的作用下,經皺摺緣排泌酸性物質,從而在破骨細胞和骨基質之間形成一個局部酸 性微環境。酸性環境使骨中的礦物質 溶解,暴露出其有機質部分,隨後被組織蛋白酶K 、抗酒石酸酸性磷酸酶 (TRACP) 及基質金屬蛋白酶-9 (MMP-9) 等酶降解。抗酒石酸酸性磷酸酶主要存在於與破骨細胞膜相聯繫的微粒體内,參與骨基質中鈣磷礦化底物的降解,可間接反映破骨細胞的活性及骨吸收的速率[ 16] 離子 、彈性蛋白 及蛋白多糖等均從細胞膜 的皺摺緣被吸收,然後進入到破骨細胞的轉移小泡進行下一步處理,最終通過胞吐作用 被轉移出破骨細胞[ 17]
目前發現無細胞毒性 的IgG2單克隆抗體 地舒單抗 (denosumab)[ 18] 核因子活化B細胞κ輕鏈增強子 (NF-κB),後者進入細胞核 影響相關基因 的表達,對破骨細胞的活化、分化、增殖及多核化和生存起關鍵作用。另一方面,則抑制RANKL 與破骨細胞及其前體表面的RANK結合,有效阻斷配體與受體 間的作用關係,從而抑制活化破骨細胞的形成、功能和存活,降低破骨細胞活性、抑制破骨細胞分化,進而阻礙腫瘤 生長[ 19]
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