In vitro activation and enzyme kinetic analysis of recombinant midgut serine proteases from the Dengue vector mosquito Aedes aegypti

Rascon, Alberto, Gearin, Johnathon, Isoe, Jun, Miesfeld, Roger

January 2011

BACKGROUND:The major Dengue virus vector Aedes aegypti requires nutrients obtained from blood meal proteins to complete the gonotrophic cycle. Although bioinformatic analyses of Ae. aegypti midgut serine proteases have provided evolutionary insights, very little is known about the biochemical activity of these digestive enzymes.RESULTS:We used peptide specific antibodies to show that midgut serine proteases are expressed as zymogen precursors, which are cleaved to the mature form after blood feeding. Since midgut protein levels are insufficient to purify active proteases directly from blood fed mosquitoes, we engineered recombinant proteins encoding a heterologous enterokinase cleavage site to permit generation of the bona fide mature form of four midgut serine proteases (AaET, AaLT, AaSPVI, AaSPVII) for enzyme kinetic analysis. Cleavage of the chromogenic trypsin substrate BApNA showed that AaET has a catalytic efficiency (kcat/KM) that is ~30 times higher than bovine trypsin, and ~2-3 times higher than AaSPVI and AaSPVII, however, AaLT does not cleave BApNA. To measure the enzyme activities of the mosquito midgut proteases using natural substrates, we developed a quantitative cleavage assay based on cleavage of albumin and hemoglobin proteins. These studies revealed that the recombinant AaLT enzyme was indeed catalytically active, and cleaved albumin and hemoglobin with equivalent efficiency to that of AaET, AaSPVI, and AaSPVII. Structural modeling of the AaLT and AaSPVI mature forms indicated that AaLT is most similar to serine collagenases, whereas AaSPVI appears to be a classic trypsin.CONCLUSIONS:These data show that in vitro activation of recombinant serine proteases containing a heterologous enterokinase cleavage site can be used to investigate enzyme kinetics and substrate cleavage properties of biologically important mosquito proteases.

trypsin

Aedes aegypti

hemoglobin

serum albumin

zymogen

The Role of the Propeptide and its Residues in Activation and Secretion of Elastase, an M4 Metalloprotease Secreted by Pseudomonas aeruginosa

Boice, Emily

27 April 2011

Pseudomonas aeruginosa secretes several proteases associated with pathogenesis, but the most abundant and active is elastase (M4 metalloendopeptidase). Elastase (lasB), is first synthesized as a preproenzyme, with a signal peptide, an 18-kDa N-terminal propeptide, and a 33-kDa mature domain. The propeptide functions as an intramolecular chaperone that is required for the folding and secretion of elastase, but ultimately is proteolytically removed and degraded. Previous research has identified the conserved residues in the propeptide of elastase as compared to other M4 protease precursors and showed some among them to be important for the production of active elastase. In this project, the ability of the propeptide alone to fold into a defined secondary structure was explored and a molecular model was created. Furthermore, the effects of substitutions on conserved residues in the propeptide of plasmid-encoded lasB pro alleles were assessed by expressing them in a lasB propeptide mutant. The kinetics of elastase activity in culture supernatants was quantitated using a fluorescent substrate, Abz-AGLA-p-Nitro-Benzyl-Amide, to provide an accurate assessment of the effects of mutant propeptides. In vitro refolding studies were also performed to determine the effects of specific substitutions on foldase activity of the propeptide. When wild-type propeptide and mature elastase were denatured as separate proteins in guanidine-HCl buffer and renatured together, restoration of activity of the refolded elastase was measured, which was propeptide-dependent. Several mutant propeptides have now been shown to have defects using this in vitro foldase assay. Additional mutants were near wild-type activity level suggesting their role in recognition by the secretion apparatus. Residue locations were determined on a molecular model of the complex and confirmed the role of the secretion mutants as residues on the exterior. Residues that had diminished ability to refold in the in vitro assay were found to be in the interior parts of the complex, confirming their ability to be critical residues at the interface of the proteins or important in the stability of the propeptide’s intrinsic structure. The goal was to perform a series of comprehensive analyses of the propeptide and its conserved residues in order to determine its role as an intramolecular chaperone.

zymogen

metalloprotease

Pseudomonas

enzyme

Medicine and Health Sciences

The Role of N- and C-terminal Amino Acids to Prosegment Catalyzed Folding in Porcine Pepsinogen A

Myers, Brenna

09 May 2012

This thesis is an investigation of the role of the prosegment (PS) of pepsinogen in the binding, refolding and inhibition of pepsin. Native pepsin (Np) is irreversibly denatured, and folds to a stable, non-native state under refolding conditions, termed refolded pepsin (Rp) (Dee and Yada 2010). When added separately, the PS binds Rp, catalyzes folding to the native-like state and inhibits Np (Dee and Yada 2010). It was hypothesized, owing to the high sequence conservation, that N-terminal PS residues are critical to PS catalyzed folding. Synthetic peptides of N-terminal truncations (N16, N29), C-terminal truncations (C15, C28), and full length, wild-type (Wt) PS were examined. N-terminal residues were required for binding to Rp and catalyzing folding, while both N29 and C28 truncations had similar inhibition constants. Remarkably, the foldase activity of N-terminal truncation (N29) was only 2.5 fold slower than Wt, supporting that PS foldase activity is stored almost entirely within the highly conserved N29 region.

prosegment

truncations

catalyzed folding

aspartic peptidase

prosegment inhibition

zymogen

Strukturní a funkční analýza katepsinu B1 z krevničky Schistosoma mansoni / Structural and functional analysis of cathepsin B1 from the blood fluke, Schistosoma mansoni

Jílková, Adéla

January 2014

Schistosomiasis is a serious infectious disease that afflicts over 200 million people in tropical and subtropical regions. It is caused by Schistosoma blood flukes that live in human blood vessels and obtain nutrients from host hemoglobin, which is degraded by digestive proteases. Current therapy relies on a single drug and concern over resistance necessitates new drug development. In Schistosoma mansoni, cathepsin B1 (SmCB1) is a critical digestive protease that is a target molecule for therapeutic interventions. This thesis provides a comprehensive characterization of SmCB1 focused on structure-activity relationships and inhibitory regulation based on six crystal structures solved for SmCB1 molecular forms and complexes. SmCB1 is biosynthesized as an inactive zymogen in which the N-terminal propeptide operates as a natural intra-molecular inhibitor by blocking the active site. Detailed biochemical and structural analyses have identified a new and, so far, unique mechanism of SmCB1 zymogen activation through which the propeptide is proteolytically removed and the regulatory role of glycosaminoglycans in this process has been described. A study of SmCB1 proteolytic activity has revealed that the enzyme acts in two modes, as endopeptidase and exopeptidase, which makes it an efficient tool for host...

Regulation of pancreatic and parotid zymogen granule chloride and potassium ion conductance pathways by cytosol nucleotides: Phosphorylation-dependent and -independent mechanisms

Thevenod, Frank

January 1993

No description available.

Biology, Animal Physiology