Scozzafava A, Supuran C T
Laboratorio di Chimica Inorganica e Bioinorganica, Università degli Studi, Via Gino Capponi 7, I-50121 Florence, Italy.
J Med Chem. 2000 Oct 5;43(20):3677-87. doi: 10.1021/jm000027t.
The 14 different carbonic anhydrase (CA, EC 4.2.1.1) isozymes as well as the 23 different matrix metalloproteinases (MMPs) isolated up to now in higher vertebrates play important physiological functions in these organisms. Unsubstituted sulfonamides act as high-affinity inhibitors for the first type of these enzymes, whereas hydroxamates strongly inhibit the latter ones. Since the active site geometry around the zinc ion in these two types of metalloenzymes is rather similar, we tested whether sulfonylated amino acid hydroxamates of the type RSO(2)NX-AA-CONHOH (X = H, benzyl, substituted benzyl; AA = amino acid moiety, such as Gly, Ala, Val, Leu) with well-known inhibitory properties against MMPs and Clostridium histolyticum collagenase (ChC, another zinc enzyme related to the MMPs) might also act as CA inhibitors. We also investigated whether N-hydroxysulfonamides of the type RSO(2)NHOH (which are effective CA inhibitors) inhibit MMPs and ChC. Here we report several potent sulfonylated amino acid hydroxamate CA inhibitors (with inhibition constants in the range of 5-40 nM, against the human isozymes hCA I and hCA II, and 10-50 nM, against the bovine isozyme bCA IV), as well as preliminary SAR for this new class of non-sulfonamide CA inhibitors. Some N-hydroxysulfonamides also showed inhibitory properties (in the micromolar range) against MMP-1, MMP-2, MMP-8, MMP-9, and ChC. Thus, the SO(2)NHOH group is a new zinc-binding function for the design of MMP inhibitors. Both CA as well as MMPs are involved, among others, in carcinogenesis and tumor invasion processes. On the basis of these findings, we suggest that the mechanism of antitumor action with some hydroxamate inhibitors might also involve inhibition of some CA isozymes (such as CA IX, CA XII, and CA XIV) present only in tumor cell membranes, in addition to collagenases/gelatinases of the MMP type. Our data also suggest that it should be possible to develop dual enzyme inhibitors that would strongly inhibit both these metalloenzymes, CAs and MMPs, based on the nature of the R, AA, and X moieties in the above formula. Compact X (such as H) and AA (such as Gly) moieties favor CA over MMP inhibition, whereas bulkier X (benzyl, substituted benzyl, etc.) and AA (such as Val, Leu) moieties and substituted-aryl R groups are advantageous for obtaining potent MMP and ChC inhibitors, which show lower affinity for CA.
目前在高等脊椎动物中分离出的14种不同的碳酸酐酶(CA,EC 4.2.1.1)同工酶以及23种不同的基质金属蛋白酶(MMP)在这些生物体中发挥着重要的生理功能。未取代的磺酰胺可作为这类酶中第一种酶的高亲和力抑制剂,而异羟肟酸则强烈抑制后者。由于这两类金属酶中锌离子周围的活性位点几何结构相当相似,我们测试了具有已知抗MMP和溶组织梭菌胶原酶(ChC,另一种与MMP相关的锌酶)抑制特性的RSO(2)NX-AA-CONHOH型(X = H、苄基、取代苄基;AA = 氨基酸部分,如甘氨酸、丙氨酸、缬氨酸、亮氨酸)磺酰化氨基酸异羟肟酸是否也可作为CA抑制剂。我们还研究了RSO(2)NHOH型N-羟基磺酰胺(它们是有效的CA抑制剂)是否抑制MMP和ChC。在此我们报告了几种强效的磺酰化氨基酸异羟肟酸CA抑制剂(对人同工酶hCA I和hCA II的抑制常数在5 - 40 nM范围内,对牛同工酶bCA IV的抑制常数在10 - 50 nM范围内),以及这类新型非磺酰胺CA抑制剂的初步构效关系。一些N-羟基磺酰胺对MMP-1、MMP-2、MMP-8、MMP-9和ChC也表现出抑制特性(在微摩尔范围内)。因此,SO(2)NHOH基团是设计MMP抑制剂的一种新的锌结合功能基团。CA和MMP都参与了多种过程,包括致癌作用和肿瘤侵袭过程。基于这些发现,我们认为一些异羟肟酸抑制剂的抗肿瘤作用机制除了抑制MMP类型的胶原酶/明胶酶外,还可能涉及抑制仅存在于肿瘤细胞膜中的一些CA同工酶(如CA IX、CA XII和CA XIV)。我们的数据还表明,根据上述公式中R、AA和X部分的性质,有可能开发出能同时强烈抑制这两种金属酶(CA和MMP)的双酶抑制剂。紧凑的X(如H)和AA(如甘氨酸)部分有利于抑制CA而非MMP,而较大的X(苄基、取代苄基等)和AA(如缬氨酸、亮氨酸)部分以及取代芳基R基团有利于获得对CA亲和力较低的强效MMP和ChC抑制剂。
