The cathelicidin derived human peptide LL37 has a broad spectrum of antimicrobial and immunomodulatory activities. The large variety of biological activities makes LL37 a very promising candidate for clinical applications. The production of biologically active LL37 in large amounts with reduced costs can only be achieved using recombinant techniques. In this work, LL37 has been cloned to the N- and C-termini of a family III carbohydrate-binding module fused to the linker sequence (LK-CBM3) from Clostridium thermocellum; both constructions (LL37-LK-CBM3 and LK-CBM3-LL37) were cloned into the pET-21a vector. A formic acid recognition site was introduced between the two modules, allowing the isolation of LL37 after chemical cleavage.
The recombinant proteins were expressed in Escherichia coli BL21 (DE3) and solubilized with Triton X-100. The purification was achieved using cellulose CF11 fibers, taking advantage of the CBM3 specific affinity for cellulose; after hydrolysis with formic acid, LL37 was further purified by reverse-phase HPLC, as confirmed by MALDI-TOF mass spectrometry. The production and purification methodology developed in this work compares advantageously to other protocols previously described, having fewer purification steps. Only the recombinant LL37 obtained from the C-terminally fused protein (LK-CBM3-LL37) showed antibacterial activity against E. coli K12, with a MIC of 180 μg/ml.University of Porto. Institute of Molecular Pathology and Immunology. Proteomics Unit (IPATIMUP)Fundação para a Ciência e a Tecnologia (FCT) - SFRH/BD/27404/200

Domingues, Lucília

Gama, F. M.

Ramos, Reinaldo Rodrigues

Protein Expression and Purification

[Excerpt] Introduction: LL-37 (LLGDFFRKSKEKIGKEFKRIVQRIKDFLRNLVPRTES) is a very promising human cationic peptide with 37 aminoacids and α-helix structure. It has been shown to exhibit a broad spectrum of antimicrobial activity and to have additional defensive roles such as regulating the inflammatory response and chemo-attracting cells of the adaptative immune system to wound or infection sites, binding and neutralizing lipopolysaccharides (LPS), promoting angiogenesis, reepithelialization and wound closure. [...

Universidade do Minho: RepositoriUM

                      ESCHERICHIA COLI EXPRESSION AND PURIFICATION OF LL37 FUSED TO A FAMILY III CARBOHYDRATE-BINDING MODULE FROM CLOSTRIDIUM THERMOCELLUM  Reinaldo Ramos, Lucília Domingues and Miguel Gama  Department of Biological Engineering  E-mail: reinaldo_ramos@deb.uminho.pt   KEYWORDS Antimicrobial peptide; LL37; CBM3; Cellulose; Formic acid   INTRODUCTION  Antimicrobial peptides (AMPs) are part of the innate immune system and have a large spectrum of antimicrobial activities against Gram-positive and Gram-negative bacteria, fungi (Ajesh and Sreejith 2009) and viruses (Hancock and Diamond 2000).  In mammals, defensins and cathelicidins represent the two major types of AMPs. The hCAP-18/LL37 is the only human cathelicidin. The antimicrobial peptide is referred to as LL37, since it has a 37 aminoacids sequence starting with two leucines. It is a 4.5 kDa, cationic (+6), amphipathic α-helical peptide, with a broad spectrum of antimicrobial activity. Besides its protective effect against infections, a variety of other biological activities have been described.   Family-III CBDs normally comprise ~150 amino acids residues and have been identified in many different bacterial enzymes, and also in non-hydrolytic proteins (Tormo, Lamed et al. 1996). Clostridium thermocellum produces a multi-enzyme complex of cellulases and hemicellulases, termed the cellulosome, which is assembled by the scaffoldin protein CipA. Binding of the cellulosome to the plant cell wall is driven by the action of the CipA family 3 CBM (CBM3), which presents high affinity for crystalline cellulose (Guerreiro, Fontes et al. 2008).  In this work, we describe the successful cloning, expression and purification of LL37 using the CBM3 from Clostridium thermocellum as fusion partner. The CBM3 is overexpressed in E. coli and it is possible to take advantage of its affinity properties to purify recombinant proteins on cellulose fibers, reducing significantly the costs of purification.   RESULTS AND DISCUSSION  Expression and Purification of Recombinant Proteins  The protein LL37 was successfully cloned at the N-terminal of the LK-CBM3 in the expression vector pET21-a. After transformation of the recombinant plasmid into E. coli BL21 (DE3), , the production of the protein (~27 kDa) in the soluble form was only achieved using the nonionic detergent, Triton X-100 (figure 1).         Figure 1 – Expression of recombinant protein CBM3-LL37. Mw: protein molecular weight marker – 1: insoluble fraction – 2: soluble fraction – 3: Triton X-100 solubilized fraction.   Chemical Cleavage and Purification of LL37 The chemical cleavage of the recombinant protein was performed, in this work, with formic acid 50%, at 50ºC for 24h. LK-CBM3-LL37 protein was first purified on cellulose.  Semana de Engenharia 2010 Guimarães, 11 a 15 de Outubro    EXAMPL  PAPER and EXAMPLE EXTE ED ABSTRACT  John J.Smith and Mary M.Doe Department of Civil Engineering E-mail: JJSmith@civil.uminho.pt   KEYWORDS Model, ! in the C-Ky, X-Y-Z Analysis.  ABSTRACT Begin each paper with an bstract (100-200 words) that summarizes the topic and import nt results presented in the paper. It should start in the left column, approximately 8 cm from the top edge of the paper, and 2 cm from the left edge. Include the abstract heading as shown. Use the bold version of your font and type in caps. Skip a line space, then begin the abstract t the left margin. The abstract should pref rably not cont in formulas, pictures, or references.  PREPARING THE REMAINING PAGES For the remaining pages follow the general guidelines below:  MAJOR HEADINGS Type in capitals, beginning flush with left-hand margin. Use a bold font. Skip half a line space, then begin.  Subheadings Capitalize the first letter of each word, beginning flush with left-hand margin. Use a bold font. Skip half a line space, then begin.  Secondary Subheadings.  Try to avoid secondary subheadings as much as possible. Use the standard font or the italic version of the font (in this case Times Italic 10). Capitalize the first letter of each word. Text follows on the next line, do not skip a line space.  MATHEMATI AL NOTATIONS AND EQUATIONS Each displayed equation should be proceded and followed by a half blank line. Display only the most important equations and number only the displaced  equations that are explicitly referenced within the text. Within the display enclose the equatiuon number in parentheses and  place it flush with the right-hand margin of the column, for example:  x(t) = A(t)x(t) + w(t) + u(t)          (1)  Within the text ach reference to an equation number should also be enclosed in parentheses as in this reference to Equation (1) above. The equation should preferably also be 10 point.  TABLES AND ILLUSTRATIONS All artwork, captions, graphics, and tables will be reproduced exactly as you submit them.  Figures and tables should be centered within a column. A figure or table that is wider then one column may be centered between the columns, but it should not extend beyond the column edges A figure or table that is wider than both columns should be set landscape. The top of the figure or table should be aligned with the left-column edge and it should occupy the entire page (but not outside the  24,7cm by 17cm rectangle). Figures and tables are numbered sequentially, but seperately using Arabic numerals  Figures should appear following the paragraph on which the figure is first referenced. Center the figure number and the caption under the figure using the following format.   Figures 1: Capitalize Caption with No-Peri d  Tables should appear in the document following the paragraph in which the table is first referenced. Center the table number and the caption above the table using the following format.  Table 1: Capitalize Caption with No-Period   R  mg 3 5 10 5 0,10 0,20 0,05 10 0,15 0,40 0.10 20 0,20 0,80 0,15 30 0,25 1,60 0,20 Then, formic acid was applied directly on the CF11 fibres with the bound protein.     Figure 2 – Formic acid cleavage of LL37. Mw: protein molecular weight marker – 3: insoluble fraction – 4: supernatant of cleaved CBM3-LL37.   The soluble supernatant, with a large proportion of LL37, was then subjected to RP-HPLC for improved purification. The purification of LL37 was successfully achieved. The fractions corresponding to the major peaks were collected and the purity of the peptide was confirmed on 16.5% Tris-tricine gel and MALDI-TOF. Figure 3 presents eluted fractions from RP-HPLC. The lane 4 demonstrates the purity of the peptide.   Figure 3 – RP-HPLC of eluted fractions. Mw: protein molecular weight marker; lanes 1-4: eluted fractions of cleaved LK-CBM3-LL37.  Antibacterial Activity  P-LL37 antibacterial activity was tested against E. coli K12. The concentration of the peptide was quantified by UV spectroscopy using the Waddell’s method (Waddell 1956). Figure 4 demonstrates that P-LL37 has antimicrobial activity, with a MIC of about 180 μg/ml (40 μM).   Figure 4 - Antibacterial activity of P-LL37 against E. coli K12   REFERENCES  Ajesh, K. and K. Sreejith (2009). "Peptide antibiotics: An alternative and effective antimicrobial strategy to circumvent fungal infections." Peptides 30(5): 999-1006. Guerreiro, C. I., C. M. Fontes, et al. (2008). "Escherichia coli expression and purification of four antimicrobial peptides fused to a family 3 carbohydrate-binding module (CBM) from Clostridium thermocellum." Protein Expr Purif 59(1): 161-8. Hancock, R. E. and G. Diamond (2000). "The role of cationic antimicrobial peptides in innate host defences." Trends Microbiol 8(9): 402-10. Tormo, J., R. Lamed, et al. (1996). "Crystal structure of a bacterial family-III cellulose-binding domain: a general mechanism for attachment to cellulose." EMBO J 15(21): 5739-51. Waddell, W. J. (1956). "A Simple Ultraviolet Spectrophotometric Method for the Determination of Protein." Journal of Laboratory and Clinical Medicine 48(2): 311-314.  AUTHOR BIOGRAPHY   REINALDO RAMOS 2006- : Biochemistry and Biotechnology PhD at the department of Biological Engineering, Univ. Minho 2003-2005: Biotechnology Master degree  at the department of Biological Engineering, Univ. Minho 1997-2002: Biological Engineering degree, Univ. Minho  reinaldo_ramos@deb.uminho.pt 

Escherichia coli expression and purification of LL37 fused to a family III carbohydrate-binding module from Clostridium thermocellum

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Universidade do Minho: RepositoriUM

Universidade do Minho: RepositoriUM

Universidade do Minho: RepositoriUM