Human Aminopeptidases: a Review of the Literature

Human Aminopeptidases: a Review of the Literature

Sanderink et al: Aminopeptidases, a review 795 J. Clin. Chem. Clin. Biochem. Vol. 26, 1988, pp. 795-807 © 1988 Waiter de Gruyter & Co. Berlin · New York Human Aminopeptidases: A Review of the Literature By G.-J. Sanderink, Y. Artur and G. Siesf Laboratoire du Centre de Medecine Preventive, UA CNRS n° 597, Vandoeuvre-les-Nancy, France (Received April 5/August 1, 1988) Summary: The aminopeptidases constitute a group of enzymes with closely related activities. In clinical chemistry the analysis of the aminopeptidases and of their multiple forms in serum has for a long time been hindered by considerable confusion concerning their identification, and by a lack of characterization. This is in part due to the often large, and sometimes overlapping substrate specificities of the aminopeptidases. This paper reviews the biochemical properties of the different aminopeptidases, the specificities of the assays used for their analysis in serum, some aspects of their multiple forms — which are especially known to occur for alanine äminopeptidase (EC 3.4.11.2) — and the importance of the determination of aminopeptidases and their multiple forms in clinical chemistry. Introduction ificities, pH optima, activators, etc. A list of some Aminopeptidases are enzymes which hydrolyse pep- human aminopeptidases acting on polypeptides is tide bonds near the N-terminal end of polypeptides. given in table 1. They can be subdivided into aminopeptidases which — substrate specificities; the different aminopepti- hydrolyse the first peptide bond (aminoacyl-peptide dases have a closely related enzymatic activity with hydrolases and iminoacyl-peptide hydrolases) and sometimes broad specificities. These specificities those which remove dipeptides from polypeptide overlap, so that many natural and synthetic sub- chains (dipeptidyl-peptide hydrolases). Some pepti- strates may be hydrolyzed by more than one en- dases act only on dipeptides or tfipeptides and may zyme. This is especially the case when the substrate also be considered as aminopeptidases. is a polypeptide. Aminopeptidases are present in many human tissues — post-translational modifications; these are espe- and body fluids. They are generally zinc-metalloen- cially known to occur for alanine äminopeptidase. zymes. They are thought to be involved in the metab- The modifications which lead to the presence of olism of proteins and various peptide hormones. multiple forms are: o glycation According to the method and conditions of analysis, limited proteolysis several forms of äminopeptidase activity can be de- aggregation with other proteins or phospho- termined in human plasma and other tissues. This lipids. heterogeneity has several causes: Taking some of these aspects into consideration, we — different gene loci; several proteins are synthesized shall discuss the main human aminopeptidases of with an äminopeptidase activity. These enzymes interest in clinical chemistry, excluding dipeptidases differ in immunological properties, substrate spec- and dipeptidyl-peptide hydrolases. J. Clin. Chem. Clin. Biochem. / Vol. 26,1988 / No. 12 796 Sanderink et al.: Aminopeptidases, a review Tab. 1. Human aminopeptidases Enzyme Substrate Remarks specificities 2+ 2 Leucine aminopeptidase leu-X- Mg , Mn + activation; EC 3.4.11.1 (AA-X-)* basic pH optimum; ' ' does not hydrolyse chromogenic substrates 2+ AJanine aminopeptidase ala-X- some activation by Co EC 3.4.1 1.2 (AA-X-) Cystyl aminopeptidase leu-X- no inhibition by bestatin and amastatin; EC 3.4.1 1.3 (cys-X-, AA-X-) heat labile asp-X- activated by Ca2+; Aminopeptidase A 2+ EC 3.4.1 1.7 glu-X- for glu-substrates also activated by Ba Aminopeptidase B lys-X- activation by Cl" and Br~; EC 3.4.1 1.6 arg-X- unstable 2 Aminopeptidase P X-pro- Mn + activation EC 3.4.11.9 Tripeptidase leu-(gly-gly) acts on tripeptides only; EC 3.4.11.4 giy(giy-giy) no inhibition by amastatin Dipeptidases AA-AA act on dipeptides only EC 3.4.13.- Dipeptidyl-peptidases (AA-AA)-X- remove dipeptides EC 3.4.14.- *AA = amino acid Aminopeptidases from Different Gene Loci peptidase was not found to hydrolyse the chromo- genic substrates leucyl-4-nitroanilide, leucyl-ß-na- Leucine aminopeptidase phthylamide or alanyl-4-nitroaiiilide (3, 10). Leucine aminopeptidase ( -aminoacyl-peptide hydro- lase (cytosol), EC 3.4.11.1) was discovered by Lin- Alanine aminopeptidase derstrom-Lang (1) in 1929. It hydrolyses preferentially, but not exclusively, peptide bonds adjacent to an N- Alanine aminopeptidase (oc-aminoacyl-peptide hydro- terminal leucine residue, as in leucinamide and leu- lase (microsomal), EC 3.4.11.2, arylamidase, amino- cylglycine (2, 3). Leucine aminopeptidase has mainly peptidase M, aminopeptidase N) is probably the ami- been studied in bovine lens and pig liver (4 — 7). It is nopeptidase which has been studied most extensively. a zinc-metalloenzyme, generally localized in cytosolic Alanine aminopeptidase hydrolyses preferentially nat- subfractions, and it is present in liver, lung, stomach, ural or synthetic substrates with an N-terminal alan- kidney, intestine, serum and leukocytes, as well as ine residue. Other amino acids, especially leucine, may other tissues (3, 8, 9). also be removed hydrolytically, with the exception of proline. The lowest Km values are found with methi- Leucine aminopeptidase is immunologically distinct onine-substrates (2, 11 — 16). from alanine aminopeptidase (8). Lederne et al. (10) purified two forms of leucine aminopeptidase activity Alanine aminopeptidase may hydrolyse several bio- from human liver which differed in their isoelectric logically active peptides, e. g. met-lys-bradykinin and points. Kohno et al. (3) recently purified the leucine lys-bradykinin (17). Alanine aminopeptidase from rat aminopeptidase from liver cytosol by immunoaffinity brain and hog aorta are capable of hydrolysing (riiet5)- chromatography. Liver leucine aminopeptidase is a enkephalin and (Ieu5)-enkephalin (18—20). In enzyme hexamer (MT 360 000) consisting of three dimers with assays the most frequently used substrates are 4- two different subunits each (Mr 53 000 and 65 000). nitroanilides and ß-naphthylamides of alanine and Human leucine aminopeptidase has an optimum at leucine. 2 2 pH 10, is typically activated by Mg + and Mn +, Human alanine aminopeptidase has been found to be 2 2 and inhibited by Zn +, Co *, complexing agents, ptesent in virtually all tissues Studieid, with relatively bestatin and amastatin. Human liver leucine amino- high specific activities in the brush border membranes J. Clin. Chem. Clin. Bioehem. / Vol. 26,1988 / No. 12 Sanderink et al.r Aminopeptidases, a review 797 of kidney proximal tubules and intestine and in bile aminopeptidase. The most rapidly hydrolysed sub- canalicular membranes (21 —27). Human alanine ami- strate was leucyl-4-nitroanilide, followed by leucyl-ß- nopeptidase has been purified from liver (8, 12, 28 — naphthylamide and S-benzyl-cysteyl-4-nitroanilide. 30), kidney (11, 31-33), intestine (13, 34, 35), pla- The preparations also showed lysyl-ß-naphthylami- centa (31, 36) and blood plasma (37, 38). Relative dase activity, while the Fmax of cystyl-di-ß-naphthyl- molecular mass estimations of the enzyme range from amide hydrolysis was only 7% of that of leucyl-ß- about 150000 (39—41) (obtained by electrophoresis naphthylamide. One difference between the two pur- of the non-purified serum enzyme) to about 240 000 ified preparations was the relatively high alanyl-ß- for purified enzymes by gel filtration (16, 28, 42). naphthylamidase acitivity of the placental enzyme Starnes & Belial (28) noticed an equilibrium between preparation. The preferential hydrolysis of leucyl- allS 000 monomeric form and a 235 000 dimeric form arylamides by cystyl aminopeptidase is a general find- of liver alanine aminopeptidase in dilute salt solutions. ing (36, 38, 40, 48, 56). Some characteristic properties Each 118000 unit contains one atom of zinc (43). of cystyl aminopeptidase which distinguish it from Alanine aminopeptidase is a glycoprotein, with a car- some other aminopeptidases, are its heat lability and bohydrate part presenting between 12 and 21% of its resistance to methionine, bestatin and amastatin in- mass, depending on the tissue source (11, 28, 31, 37). hibition (15, 57). Alanine aminopeptidase may contain a large number It is generally accepted that cystyl aminopeptidase in of sialic acid groups, which explains the rather low serum is derived from placental lysosomes (54, 55, isoelectric points, from pH 3.3 — 3.6 (liver, serum en- 58), but comparisons of studies on placental and zyme) to pH 4.7 (kidney, pancreas) (8, 28, 40, 44). serum cystyl aminopeptidase are hindered by the fact Alanine aminopeptidase is generally found in mem- that the placenta contains several other soluble and brane fractions obtained by ultracentrifugation. It can membrane-bound aminopeptidases (59, 60). The sub- be solubilized from tissues by autolysis or by proteo- strate specificities are rather broad, and pH optima lytic enzymes such as papain, bromelain and trypsin, and the action of effectors are often found to be or by extraction with detergents (22, 25). Studies on substrate- or tissue-dependent (55, 61, 62). It has been alanine aminopeptidase of pig intestine have shown shown that the placenta also contains aminopeptidase that alanine aminopeptidase is anchored in the mem- A (63) and microsomal alanine aminopeptidase, brane by a small hydrophobic polypeptide which is which is immunologically different from serum cystyl removed by the solubilizing enzymes

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