Recombinant human collagens:characterization of type II collagen expressed in insect cells and production of types I-III collagen in the yeast <em>Pichia pastoris</em>

Nokelainen, M. (Minna)

22 August 2000

Abstract An efficient system for expressing recombinant human collagens is expected to have numerous scientific and medical applications, but this is difficult to achieve because most systems do not have sufficient levels of activity of prolyl 4-hydroxylase, the key enzyme of collagen synthesis. A recombinant form of human type II collagen, the main structural component of cartilage, was produced here in insect cells by coinfecting them with two baculoviruses, one coding for the proα chains of human type II procollagen, and the other for both the α and β subunits of human prolyl 4-hydroxylase. The amino acid composition of the recombinant form was very similar to that of the non-recombinant protein, with the exception that the hydroxylysine content was very low. The highest expression levels obtained in suspension cultures were 50 mg/l. An additional baculovirus coding for human lysyl hydroxylase was used to express type II collagen with a high hydroxylysine content. Marked differences in the rate of fibril formation in vitro and the morphology of the resulting fibrils were found between the recombinant type II collagens having 2 and 19 hydroxylysine residues/1000 amino acids, the maximal turbidity of the former being reached within 5 min, whereas the absorbance of the latter increased up to about 10 h. In addition, the latter collagen formed thin fibrils, whereas the former produced thick fibrils on a background of thin ones. The data indicate that regulation of the extent of lysine hydroxylation, and consequently of the amounts of hydroxylysine-linked carbohydrate units, may have major effects on collagen fibril formation. In order to study the expression of recombinant human collagens in yeasts, cDNAs for the proα chains of procollagens of type I, II and III were transformed into a recombinant P. pastoris strain expressing human prolyl 4-hydroxylase subunits. All the P. pastoris strains obtained produced full-length proα chains. Cells coexpressing the proα1(I) chains and prolyl 4-hydroxylase produced homotrimeric type I procollagen molecules, whereas cells coexpressing the proα1(I) and proα2(I) chains and prolyl 4-hydroxylase produced heterotrimeric molecules with the correct 2:1 chain ratio. pCα1(I) and pCα2(I) chains lacking the N propeptides assembled into pCcollagen molecules and yielded correctly folded and fully hydroxylated collagen molecules upon pepsinization. The Tm values of recombinant type I-III collagens produced in shaker flasks were about 38°C and the degree of hydroxylation of proline residues was lower than that in the corresponding non-recombinant collagens. When the recombinant collagens were produced in a 2-litre fermentor equipped with an O2 supply system, the expression levels increased markedly to 0.2–0.6 g/l. In addition, all these collagens were identical in 4-hydroxyproline content to the corresponding non-recombinant proteins, and all of them formed native-type fibrils.

procollagen

prolyl 4-hydroxylase

recombinant protein expression

Identifying Sinorhizobium meliloti Genes that Determine Fitness Outcomes

Benedict, Alexander B.

08 December 2021

The remarkable metabolic capacity of the soil-dwelling bacterium Sinorhizobium meliloti is encoded on its three circular replicons: the chromosome and two large megaplasmids, pSymA and pSymB. Despite making up 45% of the genome, the pSymA and pSymB megaplasmids can be cured from S. meliloti. This unique attribute provides an opportunity to study the essentiality of chromosomal genes in the presence or absence of nearly half the genome. By interrogating chromosomal genes via massively parallel transposon insertion sequencing (Tn-seq) in the presence and absence of pSymA and pSymB, we identified 307 genes as being essential for viability regardless of the genomic context and 104 genes as being essential specifically when the megaplasmids are absent. We also found that ten percent of genes encoded on the chromosome genetically interact with genes on pSymA and pSymB. In addition, Tn-seq data were utilized to significantly refine a metabolic model of S. meliloti, facilitating more accurate fitness predictions in user-defined nutrient and genetic contexts. Furthermore, the development of a library of barcoded transposon insertion (BarSeq) mutants has enabled us to identify genes that are essential for robust growth in hundreds of nutrient environments simultaneously. This will greatly assist efforts to assign more specific functions to the ~30% of S. meliloti genes that have remained uncharacterized over the years. S. meliloti has been studied for decades as a model organism for symbiotic communication. Its legume host, Medicago truncatula, provides fixed carbon for the bacteria in order to receive fixed nitrogen in return. The molecular dialogue between S. meliloti and M. truncatula, initiates and controls each stage of symbiotic development. When inside host cells, intracellular bacteria are subjected to an arsenal of plant-derived Nodule-specific Cysteine-Rich (NCR) peptides that induce significant morphological changes prior to nitrogen fixation. It was previously shown that a bacterial peptidase, HrrP, present in about 10% of S. meliloti isolates, could degrade host-derived peptides and give the bacterial symbionts greater fitness at the expense of the host. In a screen through peptidases conserved throughout the core S. meliloti genome, we identified one peptidase (sapA) that, when overexpressed, significantly modulates symbiotic outcome. In a manner similar to HrrP, SapA degrades NCR peptides in vitro. Additionally, expression of sapA seems to occur specifically inside the plant host providing compelling evidence that some rhizobial peptidases may have evolved away from housekeeping and toward symbiotic functions.

Genetic interaction

NCR peptide

recombinant protein expression

Life Sciences

Identification and expression of proteases C. sonorensis and C. imicola important for African horsesickness virus replication / Lihandra Jansen van Vuuren

Van Vuuren, Lihandra Jansen

January 2014

African horsesickness (AHS) is one of the most deadly diseases of horses, with a mortality rate of over 90% in horses that have not been exposed to any African horsesickness virus (AHSV) serotype previously (Howell, 1960; Darpel et al., 2011). The Orbiviruses, African horsesickness virus (AHSV) and Bluetongue virus (BTV), are primarily transmitted to their mammalian hosts through certain haematophagous midge vectors (Culicoides spp.) (Erasmus, 1973). The selective cleavage of BTV and AHSV VP2 by trypsin-like serine proteases (Marchi et al., 1995) resulted in the generation of subsequent infectious sub-viral particles (ISVP) (Marchi et al., 1995; van Dijk & Huismans, 1982). It is believed that this cleavage affects the ability of the virus to infect cells of the mammalian and vector host (Darpel et al., 2011). Darpel et al (2011) identified a trypsinlike serine protease in the saliva of Culicoides sonorensis (C. sonorensis), which also cleaves the serotype determinant viral protein 2 (VP2) of BTV. And, a similar cleavage pattern was also observed by van Dijk & Huismans (1982) and Marchi et al (1995) with the use of trypsin and chymotrypsin. Manole et al (2012) recently determined the structure of a naturally occurring African horsesickness virus serotype 7 (AHSV7) strain with a truncated VP2. Upon further investigation, this strain was also shown to be more infective than the AHSV4 HS32/62 strain, since it outgrew AHSV4 in culture (Manole et al., 2012). Therefore, through proteolytic cleavage of these viral particles, the ability of the adult Culicoides to transmit the virus might be significantly increased (Dimmock, 1982; Darpel et al., 2011). Based on these findings, it is important to investigate the factors that influence the capability of arthropod-borne viruses to infect their insect vectors, mammalian hosts and their known reservoirs. In this study, we postulated that one of the vectors for AHSV, Culicoides imicola (C. imicola), has a protease similar to the 29 kDa C. sonorensis trypsin-like serine protease identified by Darpel et al (2011). Proteins in the total homogenate of C. imicola were separated on SDS-PAGE and yielded several protein bands, one of which also had a molecular mass of around 29 kDa. Furthermore, proteolytic activity was observed on a gelatin-based sodium dodecyl sulfate polyacryamide gel electrophoresis (SDS-PAGE) gel. The activity of the protein of interest was also confirmed to be a trypsin-like serine protease with the use of class-specific protease inhibitors. A recombinant trypsin-like serine protease of C. sonorensis was generated using the pColdIII bacterial expression vector. The expressed protein was partially purified with nickel ion affinity chromatography. Zymography also confirmed proteolytic activity. With the use of the protease substrates containing fluorescent tags and class specific protease inhibitors, the expressed protein was classified as a serine protease. It was also proposed that incubation of purified AHSV4 with the recombinant protease would result in the cleavage of AHSV4 VP2, resulting in similar VP2 digestion patterns as observed in BTV by Darpel et al (2011) or the truncated VP2 of AHSV7 by Manole et al (2012). BHK-21 cell cultured AHSV4 was partially purified through Caesium chloride gradient ultracentrifugation after which the virus was incubated with the recombinant protease. Since not enough virus sample was obtained, the outcome of VP2 digestion was undetermined. In the last part of this study, it was postulated that C. imicola and C. sonorensis have the same trypsin-like serine protease responsible for the cleavage of VP2 based on the protease activity visualised in the whole midge homogenate. Since the genome of C. imicola is not yet sequenced, the sequence of this likely protease is still unknown. Therefore, we attempted to identify this C. imicola protease through polymerase chain reaction (PCR) amplification. Total isolated ribonucleic acid (RNA) of C. imicola was used to synthesize complementary deoxyribonucleic acid (cDNA). The cDNA was subjected to PCR using C. sonorensis trypsin-like serine protease-based primers. An 830 bp DNA fragment was amplified. However, sequence alignment and the basic local alignment software tool (BLAST), revealed that DNA did not encode with any other known proteins or proteases. From the literature it seems that there is a correlation between the proteases in the vector and the mammalian species that succumb to AHS (Darpel et al., 2011, Wilson et al., 2009, Marchi et al., 1995). Based on the work performed in the study, a proteolytically active protein similar to the 29 kDa protein of C. sonorensis is present in C. imicola. The 29 kDa protease of C. sonorensis can also be expressed in bacteria which could aid in future investigations on how proteolytic viral modifications affect infectivity between different host species. / MSc (Biochemistry), North-West University, Potchefstroom Campus, 2014

African horsesickness virus

Culicoides imicola

Culicoides sonorensis

Protease expression

Proteolytic activity

Recombinant protein expression

Studium proteas virů Zika a Dengue / Analysis of Zika and Dengue virus proteases

Novotný, Pavel

January 2019

in English Zika and Dengue flaviviruses are transmitted by mosquitoes in human populations living in tropical areas. They cause fevers which in the case of Dengue can lead to life threatening haemorrhagic form. There is a possible relationship between pregnant women being infected by Zika virus and higher risk of microcephaly in new-borns. The infection is currently treated mainly symptomatically. However, there is an effort to develop compounds which block viral life cycle and viral spread through organism. Viral enzymes, such as flaviviral proteases, are regarded as suitable targets for this effort. These serine proteases with chymotrypsin fold are heterodimers which consist of flaviviral non- structural proteins NS2B and NS3. NS3 domain also contains a helicase, which can be removed by gene recombination for study purposes. NS2B is a transmembrane protein, but only a hydrophilic 40 amino acid peptide is important for the interaction with NS3 domain. This peptide has a chaperon function and participates in substrate binding to the active site. In this study, six variants of recombinant proteins containing activating peptide of NS2B and protease domain of NS3 were expressed and purified. Four variants were characterized in enzymologic studies including testing of possible inhibitors. A dipeptide...

Identification and expression of proteases C. sonorensis and C. imicola important for African horsesickness virus replication / Lihandra Jansen van Vuuren

Van Vuuren, Lihandra Jansen

January 2014

African horsesickness (AHS) is one of the most deadly diseases of horses, with a mortality rate of over 90% in horses that have not been exposed to any African horsesickness virus (AHSV) serotype previously (Howell, 1960; Darpel et al., 2011). The Orbiviruses, African horsesickness virus (AHSV) and Bluetongue virus (BTV), are primarily transmitted to their mammalian hosts through certain haematophagous midge vectors (Culicoides spp.) (Erasmus, 1973). The selective cleavage of BTV and AHSV VP2 by trypsin-like serine proteases (Marchi et al., 1995) resulted in the generation of subsequent infectious sub-viral particles (ISVP) (Marchi et al., 1995; van Dijk & Huismans, 1982). It is believed that this cleavage affects the ability of the virus to infect cells of the mammalian and vector host (Darpel et al., 2011). Darpel et al (2011) identified a trypsinlike serine protease in the saliva of Culicoides sonorensis (C. sonorensis), which also cleaves the serotype determinant viral protein 2 (VP2) of BTV. And, a similar cleavage pattern was also observed by van Dijk & Huismans (1982) and Marchi et al (1995) with the use of trypsin and chymotrypsin. Manole et al (2012) recently determined the structure of a naturally occurring African horsesickness virus serotype 7 (AHSV7) strain with a truncated VP2. Upon further investigation, this strain was also shown to be more infective than the AHSV4 HS32/62 strain, since it outgrew AHSV4 in culture (Manole et al., 2012). Therefore, through proteolytic cleavage of these viral particles, the ability of the adult Culicoides to transmit the virus might be significantly increased (Dimmock, 1982; Darpel et al., 2011). Based on these findings, it is important to investigate the factors that influence the capability of arthropod-borne viruses to infect their insect vectors, mammalian hosts and their known reservoirs. In this study, we postulated that one of the vectors for AHSV, Culicoides imicola (C. imicola), has a protease similar to the 29 kDa C. sonorensis trypsin-like serine protease identified by Darpel et al (2011). Proteins in the total homogenate of C. imicola were separated on SDS-PAGE and yielded several protein bands, one of which also had a molecular mass of around 29 kDa. Furthermore, proteolytic activity was observed on a gelatin-based sodium dodecyl sulfate polyacryamide gel electrophoresis (SDS-PAGE) gel. The activity of the protein of interest was also confirmed to be a trypsin-like serine protease with the use of class-specific protease inhibitors. A recombinant trypsin-like serine protease of C. sonorensis was generated using the pColdIII bacterial expression vector. The expressed protein was partially purified with nickel ion affinity chromatography. Zymography also confirmed proteolytic activity. With the use of the protease substrates containing fluorescent tags and class specific protease inhibitors, the expressed protein was classified as a serine protease. It was also proposed that incubation of purified AHSV4 with the recombinant protease would result in the cleavage of AHSV4 VP2, resulting in similar VP2 digestion patterns as observed in BTV by Darpel et al (2011) or the truncated VP2 of AHSV7 by Manole et al (2012). BHK-21 cell cultured AHSV4 was partially purified through Caesium chloride gradient ultracentrifugation after which the virus was incubated with the recombinant protease. Since not enough virus sample was obtained, the outcome of VP2 digestion was undetermined. In the last part of this study, it was postulated that C. imicola and C. sonorensis have the same trypsin-like serine protease responsible for the cleavage of VP2 based on the protease activity visualised in the whole midge homogenate. Since the genome of C. imicola is not yet sequenced, the sequence of this likely protease is still unknown. Therefore, we attempted to identify this C. imicola protease through polymerase chain reaction (PCR) amplification. Total isolated ribonucleic acid (RNA) of C. imicola was used to synthesize complementary deoxyribonucleic acid (cDNA). The cDNA was subjected to PCR using C. sonorensis trypsin-like serine protease-based primers. An 830 bp DNA fragment was amplified. However, sequence alignment and the basic local alignment software tool (BLAST), revealed that DNA did not encode with any other known proteins or proteases. From the literature it seems that there is a correlation between the proteases in the vector and the mammalian species that succumb to AHS (Darpel et al., 2011, Wilson et al., 2009, Marchi et al., 1995). Based on the work performed in the study, a proteolytically active protein similar to the 29 kDa protein of C. sonorensis is present in C. imicola. The 29 kDa protease of C. sonorensis can also be expressed in bacteria which could aid in future investigations on how proteolytic viral modifications affect infectivity between different host species. / MSc (Biochemistry), North-West University, Potchefstroom Campus, 2014

African horsesickness virus

Culicoides imicola

Culicoides sonorensis

Protease expression

Proteolytic activity

Recombinant protein expression

Expression and analysis of recombinant human collagen prolyl 4-hydroxylase in <em>E. coli</em> and optimization of expression

Neubauer, A. (Antje)

23 May 2006

Abstract Collagen prolyl 4-hydroxylase (C-P4H) plays a central role in the biosynthesis of collagens by hydroxylating proline residues. The enzyme has been a subject of intense interest as a target enzyme for drug development. The recombinant expression of human C-P4H in prokaryotes has not yet been described. This work reports on the development of an expression system for human C-P4H in E. coli. The vertebrate C-P4H enzymes are α2β2 tetramers, consisting of two β subunits which are identical to protein disulphide isomerase (PDI), aside from the two α subunits which have the catalytic activity. The function of PDI is to keep the α subunit in a soluble and active state. Therefore, the expression system should assure the expression of the β subunit in the cell before the α subunit by using two different promoters. An active C-P4H tetramer was obtained in the periplasm of E. coli. However, further optimization for production by stepwise regulated coexpression of its subunits in the cytoplasm of a thioredoxin reductase and glutathione reductase mutant E. coli strain resulted in large amounts of human C-P4H tetramer. The exchange of four rare E. coli codons of the pdi gene and the optimized distance between ribosome binding site and translation initiation, resulted in 50-fold P4H-activity and 25 mg/l purified enzyme. Comparison of the expression level of mRNA from the α and β subunits by Sandwich hybridization identified single induction with anhydrotetracycline in fed-batch fermentations as a limiting parameter. This caused an insufficient expression level of mRNA and thereby a low yield of C-P4H. A maximum yield was obtained by repeated addition of anhydrotetracycline that led to higher mRNA levels and increased productivity. A newly developed stochastic simulation model of translational ribosome traffic in bacteria assesses the effect of codon usage to ribosome traffic and to the overall translation rate and mRNA stability. Using human PDI, it was shown that substitution of four 5' codons of the human PDI sequence that are rare in E. coli sequences, by synonymous codons preferred in E. coli led to a 2-fold increase of total PDI amount and even to a 10-fold increase of soluble PDI amount.

collagen prolyl 4-hydroxylase

mRNA analysis

optimization of expression

recombinant protein expression

Escherichia coli

Optimization of the heterologous expression of folate metabolic enzymes of Plasmodium falciparum

Goolab, Shivani

30 March 2011

Malaria is a fatal tropical disease affecting billions of people in impoverished countries world-wide. An alarming fact is that a child in Africa dies of malaria every 30 seconds that amounts to 2500 children per day (www.who.int/features/factfiles). Malaria is caused by the intraerythrocytic forms of Plasmodium species, notably P. falciparum, P. vivax, P. ovale and P. malariae (Hyde 2007). The spread of drug-resistant strains, failure of vector control programs, rapid growth rate of the parasite, and lack of a vaccine have further exacerbated the effects of malaria on economic development and human health. It is therefore imperative that novel drug targets are developed or current antimalarial drugs optimized (Foley and Tilley 1998). One such target is folate biosynthesis, given that folates and their derivatives are required for the survival of organisms (Muller et al. 2009). DHFR and DHPS are currently the only folate targets exploited however, their antifolate drugs are almost useless against parasite resistant strains. As such, guanosine-5’triphosphate cyclohydrolase I (GTPCHl) among other antifolate candidates are considered for intervention (Lee et al. 2001). Knock-out studies (of P. falciparum gtpchI) resulted in the suppression of DHPS activity (Nzila et al. 2005). Additionally, gtpchI amplified 11-fold in P. falciparum strains resistant to antifolates due to mutations in dhps and dhfr and this may be a mechanism for the compensation of reduced flux of folate intermediates (Kidgell et al. 2006; Nair et al. 2008). Over-expression of P. falciparum proteins in E. coli remains a challenge mainly due to the A+T rich Plasmodium genome resulting in a codon bias. This results in the expression of recombinant proteins as insoluble proteins sequestered in inclusion bodies (Carrio and Villaverde 2002; Mehlin et al. 2006; Birkholtz et al. 2008a). Comparative expression studies were conducted of native GTPCHI (nGTPCHI), codon optimized GTPCHI (oGTPCHI) and codon harmonized (hGTPCHI) in various E. coli cell lines, using alternative media compositions and co-expression with Pfhsp70. The nGTPCHI protein did not express because the gene consisted of codons rarely used by E. coli (codon bias). The expression levels of purified hGTPCHI were a greater in comparison to oGTPCHI using the different expression conditions. This is because codon-harmonization involves substituting codons to replicate the codon frequency preference of the target gene in P. falciparum, as such the translation machinery matches that of Plasmodium (Angov et al. 2008). Furthermore, greater expression levels of GTPCHI were achieved in the absence of Pfhsp70 due to expression of a possible Nterminal deletion product or E. coli protein. Purification conditions could be improved to obtain homogenous GTPCHI and further analysis (mass spectrometry and enzyme activity assays) would be required to determine the nature of soluble GTPCHI obtained. To improve the expression of soluble proteins the wheat germ expression system was used as an alternate host. However, GTPCHI expression was not effective, possibly due to degradation of mRNA template or the absence of translation enhancer elements. / Dissertation (MSc)--University of Pretoria, 2010. / Biochemistry / unrestricted

Folate biosynthesis

Recombinant protein expression

Guanosine 5’ triphosphate

Codon harmonization

Malaria

UCTD

Optimizing the large-scale production of Saw1 and the Saw1-Rad1-Rad10 nuclease complex for structural studies

Rashev, Margarita

January 2017

Yeast Rad1-Rad10 is a structure specific nuclease that processes branched double-strand break (DSB) repair intermediates; the persistence of which can impede normal DNA metabolism. The single strand annealing (SSA) mechanism of DSB repair acts when homologous repeats flank both sides of the DSB. End resection from the 5′ ends of the break exposes complementary sequences at the flanking repeats, which are annealed to form 3′ non-homologous flap structures. Saw1 recruits Rad1-Rad10 recruits to these 3′ non-homologous flaps, where Rad1-Rad10 incises the DNA and removes the flap. Saw1 has affinity towards branched DNA structures and forms a stable complex with Rad1-Rad10. The mechanism of both structure specific recruitment and nucleolytic activity of the Saw1-Rad1-Rad10 complex is currently unknown. To study this nuclease complex, we need to produce large quantities of pure, stable, and active recombinant protein. Using dynamic light scattering (DLS) and differential scanning fluorimetry (DSF)-based high throughput thermal stability assays, we have developed a method for large-scale production of recombinant Saw1. This optimized method has increased the stability and yield of protein, thereby allowing for future biochemical investigation of Saw1. Similarly, we have optimized the large-scale production of the higher molecular-weight complex (Saw1-Rad1-Rad10) and improved the homogeneity of the recombinant complex. We have also biochemically characterized the minimal branched DNA substrates for both Saw1 and Saw1-Rad1-Rad10. This work allows for biochemical investigation into the molecular mechanism of eukaryotic 3′ non-homologous flap removal during SSA. / Thesis / Master of Science (MSc)

DNA repair

Single strand annealing

structure selective nuclease

Rekombinantní expresse chloridového kanálu z E. coli a jeho strukturní charakterizace / Recombinant expression of chloride channel from E. coliand its structure characterization

Hausner, Jiří

January 2014

Chloride channel family has been shown to play a significant role in physiological homeostasis processes. The function mechanism of these proteins has not yet been clearly understood. Their deficiency or mutation causes serious human illnesses. Our understanding of the chloride channels' transporting mechanisms can lead to better treatment of these illnesses. As mammalian chloride channels are difficult to prepare in laboratory, the experiments are usually done on homologous chloride channels from prokaryotic organisms. The structures of prokaryotic chloride channels have been solved and moreover they are produced with high yields. Most experiments currently use protein crystallography and provide a static picture of the system. This thesis is focused on the study of structural changes of an E. coli chloride channel using hydrogen/deuterium exchange. This method enables us to monitor dynamic conformation changes dependent on pH and exchanged ions. The measurements were done for the protonated (pH 4.5) and deprotonated state (pH 7.5) and/or in the presence of various anions: Cl− , SCN− , I− , F− , TAR. (tartaric anion). The obtained results justified the theories explaining the function of chloride channel as Cl− /H+ antiporter and provided new findings. Subject words biochemistry, protein...

Charakterizace glutamátkarboxypeptidasy II, jejích blízkých homologů a jejich interakcí s ligandy / Characterization of Glutamate Carboxypeptidase II, its Close Homologs and their Interaction with Ligands

Tykvart, Jan

January 2015

Cancer, group of diseases characterized by an uncontrolled cell growth, represents one of the great challenges of modern clinical research. Currently, the standard treatment of the cancer disease relies mainly on the whole body exposition to various factors, which targets the dividing cells, combined with surgical resection of the tumor. Unfortunately, this treatment is sometimes accompanied by numerous severe side-effects (e.g., nausea, loss of hair, infertility etc.). Therefore, in the past 40 years enormous resources and effort have been invested into finding a way how to specifically target and destroy the cancerous cells. This goal has been primarily addressed by the search for molecules, mainly proteins, which are predominantly expressed in the cancerous tissues compared to the healthy cells. Glutamate carboxypeptidase II (GCPII), also known as prostate specific membrane antigen (PSMA), represents such a target since it is highly expressed in a prostate carcinoma as well as in a solid tumor neovasculature. Additionally, GCPII is widely used as a model target molecule for proof-of-principle studies on targeted drug delivery. GCPII thorough biochemical characterization is essential for its appropriate use. Therefore, our laboratory has been investigating GCPII from various perspectives for more...