Evaluation of ketone-oxime method for developing therapeutic on-demand cleavable immunoconjugates

The use of antibody molecules in immunoassay, molecular targeting, or detection techniques encompasses a broad variety of applications affecting nearly every field of medical science. In cancer therapy, monoclonal antibodies (mAb) have been used as vehicles to deliver radionuclides, toxins, or drugs to the target cancer cells. New conjugation methods are most needed to conjugate a wide variety of targeting small molecules and peptidomimatic compounds. Here, we exploited a keto-oxime method for conjugation of protease susceptible linkers to an antibody. This modified method involves two steps: (i) introduction of methyl ketone linkers (referred to as linker moiety) to the primary amines present in the antibody and (ii) conjugation of ketone linkers to aminoxy functional group present in the conjugated moiety (referred to as functional moiety). We have optimized this conjugation method and shown that approximately 10 functional moieties can be conjugated to antibody. Conjugation was verified by MALDI-TOF MS and Western blot analysis. The acidic pH conditions used in this method did not change the immune reactivity of the Ab. In addition, in vitro protease susceptibility assay was performed to validate this method for prodrug release assay as well as to remove excess radioimmune conjugates from circulation. This orthogonal method is compatible with peptides containing a thiol, amino, or carboxyl groups in the conjugation moiety.     

Evaluation of progesterone-ovalbumin conjugates with different length linkers in enzyme-linked immunosorbant assay and surface plasmon resonance-based immunoassay

A series of progesterone-4-ovalbumin (OVA) conjugates with different length linkers (4-, 11-, and 18-atoms long) were synthesized by successive aminocaproic acid homologation of 3-(pregn-4-ene-3,20-dione-4-yl)thiopropanoic acid (1) before conjugation to ovalbumin. The performance studies of these progesterone-4-ovalbumin conjugates showed that the effects of the length of linker on the antibody binding are dependent upon different immunoassay formats. In a rapid flow biosensor surface, on a BIAcore Surface Plasmon Resonance (SPR) instrument, antibody-binding capacities and response rate were dramatically increased for progesterone-4-ovalbumin conjugates when the length of the linker was incremented from 4 atoms to 11 or 18 atoms. Thus, highly sensitive SPR-based immunoassays for progesterone over a range of 0.1-50 ng ml(-1) were developed using biosensor surfaces immobilized with progesterone-ovalbumin conjugates having extended linkers. The SPR-based assays were fully competitive with conventional enzyme-linked immunosorbant assay (ELISA) but much more rapid and simple. However, there were little changes in antibody-binding performance using a conventional ELISA for the same conjugates. The progesterone-4-ovalbumin conjugate (1-OVA) had better antibody binding than its progesterone-7alpha-ovalbumin analog (2-OVA) in the SPR-based assay, but with a conventional ELISA there was no significant difference between these two isomeric conjugates.     

Modulation of single-chain antibody affinity with temperature-responsive elastin-like polypeptide linkers

Single-chain antibodies are genetically engineered constructs composed of a VH and VL domain of an antibody linked by a flexible peptide linker, commonly (GGGGS)3. We asked whether replacement of this flexible linker with peptides known to undergo environmentally induced structural transitions could lead to antibodies with controlled binding and release characteristics. To this end, we genetically modified and produced a series of anti-fluorescein single-chain antibodies with the general linker sequence (VPGXG)n, where n is 1.2 to 3 and X is Val or His, to evaluate the effects of linker length and composition. Our results indicate that single-chain antibodies containing elastin-like polypeptide linkers have equilibrium affinity (KD) comparable to wild-type (GGGGS)3 at room temperature but altered binding kinetics and faster ligand release as the temperature is raised. These results are consistent with the increased molecular order and contraction that elastin-like polypeptides are known to undergo with increased temperature. Modulation of antibody affinity using stimulus-responsive linkers may have applications in biosensors, drug delivery, and bioseparations.     

Strategy for selecting and characterizing linker peptides for CBM9-tagged fusion proteins expressed in Escherichia coli

The influence of linker design on fusion protein production and performance was evaluated when a family 9 carbohydrate-binding module (CBM9) serves as the affinity tag for recombinant proteins expressed in Escherichia coli. Two bioinformatic strategies for linker design were applied: the first identifies naturally occurring linkers within the proteome of the host organism, the second involves screening peptidases and their known specificities using the bioinformatics software MEROPS to design an artificial linker resistant to proteolysis within the host. Linkers designed using these strategies were compared against traditional poly-glycine linkers. Although widely used, glycine-rich linkers were found by tandem MS data to be susceptible to hydrolysis by E. coli peptidases. The natural (PT)(x)P and MEROPS-designed S(3)N(10) linkers were significantly more stable, indicating both strategies provide a useful approach to linker design. Factor X(a) processing of the fusion proteins depended strongly on linker chemistry, with poly(G) and S(3)N(10) linkers showing the fastest cleavage rates. Luminescence resonance energy transfer studies, used to measure average distance of separation between GFP and Tb(III) bound to a strong calcium-binding site of CBM9, revealed that, for a given linker chemistry, the separation distance increases with increasing linker length. This increase was particularly large for poly(G) linkers, suggesting that this linker chemistry adopts a hydrated, extended configuration that makes it particularly susceptible to proteolysis. Differential scanning calorimetry studies on the PT linker series showed that fusion of CBM9 to GFP did not alter the T(m) of GFP but did result in a destabilization, as seen by both a decrease in T(m) and DeltaH(cal), of CBM9. The degree of destabilization increased with decreasing length of the (PT)(x)P linker such that DeltaT(m) = -8.4 degrees C for the single P linker.     

Probing the primary structural determinants of streptokinase inter-domain linkers by site-specific substitution and deletion mutagenesis

The bacterial protein streptokinase (SK) contains three independently folded domains (α, β and γ), interconnected by two flexible linkers with noticeable sequence homology. To investigate their primary structure requirements, the linkers were swapped amongst themselves i.e. linker 1 (between α and β domains) was swapped with linker 2 (between β and γ domains) and vice versa. The resultant construct exhibited very low activity essentially due to an enhanced proteolytic susceptibility. However, a SK mutant with two linker 1 sequences, which was proteolytically as stable as WT-rSK retained about 10% of the plasminogen activator activity of rSK When the native sequence of each linker was substituted with 9 consecutive glycine sequences, in case of the linker 1 substitution mutant substantial activity was seen to survive, whereas the linker 2 mutant lost nearly all its activity. The optimal length of linkers was then studied through deletion mutagenesis experiments, which showed that deletion beyond three residues in either of the linkers resulted in virtually complete loss of activator activity. The effect of length of the linkers was then also examined by insertion of extraneous pentapeptide sequences having a propensity for adopting either an extended conformation or a relatively rigid conformation. The insertion of poly-Pro sequences into native linker 2 sequence caused up to 10-fold reduction in activity, whereas its effect in linker 1 was relatively minor. Interestingly, most of the linker mutants could form stable 1:1 complexes with human plasminogen. Taken together, these observations suggest that (i) the functioning of the inter-domain linkers of SK requires a critical minimal length, (ii) linker 1 is relatively more tolerant to insertions and sequence alterations, and appears to function primarily as a covalent connector between the α and β domains, and (iii) the native linker 2 sequence is virtually indispensable for the activity of SK probably because of structural and/or flexibility requirements in SK action during catalysis.     

High-resolution crystal structures of trimeric and rod phycocyanin

The phycobilisome light-harvesting antenna in cyanobacteria and red algae is assembled from two substructures: a central core composed of allophycocyanin surrounded by rods that always contain phycocyanin (PC). Unpigmented proteins called linkers are also found within the rods and core. We present here two new structures of PC from the thermophilic cyanobacterium Thermosynechococcus vulcanus. We have determined the structure of trimeric PC to 1.35 Å, the highest resolution reported to date for this protein. We also present a structure of PC isolated in its intact and functional rod form at 1.5 Å. Analysis of rod crystals showed that in addition to the α and β PC subunit, there were three linker proteins: the capping rod linker (L_R^8.7), the rod linker (L_R), and only one of three rod-core linkers (L_RC, CpcG4) with a stoichiometry of 12:12:1:1:1. This ratio indicates that the crystals contained rods composed of two hexamers. The crystallographic parameters of the rod crystals are nearly identical with that of the trimeric form, indicating that the linkers do not affect crystal packing and are completely embedded within the rod cavities. Absorption and fluorescence emission spectra were red-shifted, as expected for assembled rods, and this could be shown for the rod in solution as well as in crystal using confocal fluorescence microscopy. The crystal packing imparts superimposition of the three rod linkers, canceling out their electron density. However, analysis of B-factors and the conformations of residues facing the rod channel indicate the presence of linkers. Based on the experimental evidence presented here and a homology-based model of the L_R protein, we suggest that the linkers do not in fact link between rod hexamers but stabilize the hexameric assembly and modify rod energy absorption and transfer capabilities.     

重组单链抗体-低分子质量尿激酶融合蛋白在 CHO 细胞中的抗降解研究

抗人纤维蛋白单链抗体-低分子质量尿激酶(Ⅱn-UK)融合蛋白,兼有单链抗体对纤维蛋白的亲和性和尿激酶的溶栓活性,有望开发成为新型导向溶栓药物.但基于通用连接肽(G4S)3的Ⅱn-linker-UK融合蛋白在CHO细胞中表达时出现明显的降解.为了解决此问题,利用分子生物学方法,对Hn-UK融合蛋白进行了分子改造,包括置换连接肽,改变两个半分子(moiety)的相对位置,以及对连接肽附近明确的蛋白酶位点进行突变等方法,并分别研究了改造后的11种Ⅱn-1inker-UK或UK-linker-Ⅱn突变体在CHO细胞中分泌性表达时的稳定性,最终筛选到一种抗降解的突变体.     

Cellulase Linkers Are Optimized Based on Domain Type and Function: Insights from Sequence Analysis,Biophysical Measurements,and Molecular Simulation

Cellulase enzymes deconstruct cellulose to glucose, and are often comprised of glycosylated linkers connecting glycoside hydrolases (GHs) to carbohydrate-binding modules (CBMs). Although linker modifications can alter cellulase activity, the functional role of linkers beyond domain connectivity remains unknown. Here we investigate cellulase linkers connecting GH Family 6 or 7 catalytic domains to Family 1 or 2 CBMs, from both bacterial and eukaryotic cellulases to identify conserved characteristics potentially related to function. Sequence analysis suggests that the linker lengths between structured domains are optimized based on the GH domain and CBM type, such that linker length may be important for activity. Longer linkers are observed in eukaryotic GH Family 6 cellulases compared to GH Family 7 cellulases. Bacterial GH Family 6 cellulases are found with structured domains in either N to C terminal order, and similar linker lengths suggest there is no effect of domain order on length. O-glycosylation is uniformly distributed across linkers, suggesting that glycans are required along entire linker lengths for proteolysis protection and, as suggested by simulation, for extension. Sequence comparisons show that proline content for bacterial linkers is more than double that observed in eukaryotic linkers, but with fewer putative O-glycan sites, suggesting alternative methods for extension. Conversely, near linker termini where linkers connect to structured domains, O-glycosylation sites are observed less frequently, whereas glycines are more prevalent, suggesting the need for flexibility to achieve proper domain orientations. Putative N-glycosylation sites are quite rare in cellulase linkers, while an N-P motif, which strongly disfavors the attachment of N-glycans, is commonly observed. These results suggest that linkers exhibit features that are likely tailored for optimal function, despite possessing low sequence identity. This study suggests that cellulase linkers may exhibit function in enzyme action, and highlights the need for additional studies to elucidate cellulase linker functions.     

Investigation of the role of the domain linkers in separate site catalysis by Clostridium symbiosum pyruvate phosphate dikinase.

Pyruvate phosphate dikinase (PPDK) catalyzes the reversible reaction: ATP + P(i) + pyruvate <--> AMP + PP(i) + PEP using Mg2+ and NH4+ ions as cofactors. The reaction takes place in three steps, each mediated by a carrier histidine residue located on the surface of the central domain of this three-domain enzyme: (1) E-His + ATP <--> E-His-PP.AMP, (2) E-His-PP.AMP + P(i) <--> E-His-P + AMP + PP(i), (3) E-His-P + pyruvate <--> E-His + PEP. The first two partial reactions are catalyzed at an active site located on the N-terminal domain, and the third partial reaction is catalyzed at an active site located on the C-terminal domain. For catalytic turnover, the central domain travels from one terminal domain to the other. The goal of this work is to determine whether the two connecting linkers direct the movement of the central domain between active sites during catalytic turnover. The X-ray crystal structure of the enzyme suggests interaction between the two linkers that may result in their coordinated movement. Mutations were made at the linkers for the purpose of disrupting the linker-linker interaction and, hence, synchronized linker movement. Five linker mutants were analyzed. Two of these contain 4-Ala insertions within the solvated region of the linker, and three have 3-residue deletions in this region. The efficiencies of the mutants for catalysis of the complete reaction as well as the E-His + ATP <--> E-His-PP.AMP partial reaction at the N-terminal domain and the E-His + PEP <--> E-His-P + pyruvate reaction at the C-terminal domain were measured to assess linker function. Three linker mutants are highly active catalysts at both active sites, and the fourth is highly active at one site but not the other. These results are interpreted as evidence against coordinated linker movement, and suggest instead that the linkers move independently as the central domain travels between active sites. It is hypothesized that while the linkers play a passive role in central domain-terminal domain docking, their structural design minimizes the conformational space searched in the diffusion process.     

scFv multimers of the anti-neuraminidase antibody NC10: length of the linker between VH and VL domains dictates precisely the transition between diabodies and triabodies.

Single-chain Fv antibody fragments (scFvs) incorporate a polypeptide linker to tether the VH and VL domains together. An scFv molecule with a linker 5-12 residues long cannot fold into a functional Fv domain and instead associates with a second scFv molecule to form a bivalent dimer (diabody). Direct ligation of VH and VL domains further restricts association and forces three scFv molecules to associate into a trivalent trimer (triabody). We have defined the effect of linker length on scFv association by constructing a series of scFvs from anti-neuraminidase antibody NC10 in which the linker varied from one to four glycine residues. NC10 scFv molecules containing linkers of three and four residues showed a strong preference for dimer formation (diabodies), whereas a linker length of one or two glycine residues prevented the formation of diabodies and directed scFv association into trimers (triabodies). The data suggest a relatively strict transition from dimer (diabody) to trimer (triabody) upon reduction of the linker length from three to two glycine residues. Modelling studies are consistent with three residues as the minimum linker length compatible with diabody formation. Electron microscope images of complexes formed between the NC10 scFv multimers and an anti-idiotype Fab' showed that the dimer was bivalent for antigen binding and the trimer was trivalent.     

Monoclonal antibody conjugates of doxorubicin prepared with branched linkers: A novel method for increasing the potency of doxorubicin immunoconjugates

Immunoconjugates of monoclonal antibody BR96 and Doxorubicin have been prepared using a novel series of branched hydrazone linkers. Since each linker bound to the mAb carries two DOX molecules, the DOX/mAb molar ratios of these conjugates were approximately 16, twice that of those previously prepared with single-chain hydrazone linkers. The conjugates were stable at a physiological pH of 7, but released DOX rapidly at lysosomal pH 5. The branched series of BR96 conjugates demonstrated antigen-specific cytotoxicity, and were more potent in vitro than the single-chain conjugate on both a DOX (4-14-fold) and mAb (7-23-fold) basis. The results suggest that, by using the branched linker methodology, it is possible to significantly reduce the amount of mAb required to achieve antigen-specific cytotoxic activity. In this paper, the synthesis and in vitro biology of branched chain immunoconjugates are described.     

Novel immunoconjugates comprised of streptonigrin and 17-amino-geldanamycin attached via a dipeptide-p-aminobenzyl-amine linker system

Cytotoxic agents streptonigrin and 17-amino-geldanamycin were linked to monoclonal antibodies (mAbs), forming antibody–drug conjugates (ADCs) for antigen-mediated targeting to cancer cells. The drugs were conjugated with a linker construct that is labile to lysosomal proteases and incorporates a valine-alanine-p-aminobenzyl (PAB)-amino linkage for direct attachment to the electron-deficient amine functional groups present in both drugs. The resulting ADCs release drug following internalization into antigen-positive cancer cells. The drug linkers were conjugated to mAbs cAC10 (anti-CD30) and h1F6 (anti-CD70) via alkylation of reduced interchain disulfides to give ADCs loaded with 4 drugs/mAb. The streptonigrin ADCs were potent and immunologically specific on a panel of cancer cell lines in vitro and in a Hodgkin lymphoma xenograft model. We conclude that streptonigrin ADCs are candidates for further research, and that the novel linker system used to make them is well-suited for the conjugation of cytotoxic agents containing electron-deficient amine functional groups.     

The role of linkers in the reassembly of the 3.6 MDa hexagonal bilayer hemoglobin from Lumbricus terrestris.

The extent and kinetics of reassembly of the four groups of linkers L1-L4 with 213 kDa subassemblies of twelve globin chains D, (bac)3(d)3, isolated from the approximately 3.6 MDa hexagonal bilayer (HBL) hemoglobin (Hb) of Lumbricus terrestris, was investigated using gel filtration. The reassembled HBL's were characterized by scanning transmission electron microscopic (STEM) mass mapping and their subunit content determined by reversed-phase chromatography. In reassembly by method (A), the linkers isolated by RP-HPLC at pH approximately 2.2 were added to D at neutral pH; in method (B), the linkers were renatured at neutral pH and then added to D. With method (A) the percentage of HBL reassembly varied from >/=13% in the absence of Ca(II) to /=75%), with ternary and binary linker combinations (40-50%) and with individual linkers producing yields increasing in the following order: L1=1-3%, L2 approximately L3=10-20% and L4=35-55%. The yield was two- to eightfold lower with method (B), except in the case of linkers L1-L3. Although the reassembly kinetics were always biphasic, with t1/2=0.3-3.3 hours and 10-480 hours, the ratio of the amplitudes fast:slow was 1:0.6 with method (A) and 1:2.5 with method (B). These results are consistent with a scheme in which the slow HBL reassembly is dependent on a slow conversion of linker conformation at neutral pH from a reassembly incompetent to a reassembly competent conformation. Although all the linkers self-associate extensively at neutral pH, forming complexes ranging from dimers to >18-mers, the size of the complex does not affect the extent or rate of reassembly. The oxygen binding affinity of reassembled HBLs was similar to that of the native Hb, but their cooperativity was lower. A model of HBL reassembly was proposed which postulates that binding of linker dimers to two of the three T subunits of D causes conformational alterations resulting in the formation of complementary binding sites which permit lateral self-association of D subassemblies, and thus dictate the formation of a hexagonal structure due to the 3-fold symmetry of D.     

The MURFI linker for multiple reading frame insertion of a sense or nonsense codon into DNA.

Blunt-end palindromic DNA linkers with a central restriction site have been designed for the multiple reading frame insertion (abbreviated MURFI) of a sense or nonsense codon into DNA. We have utilized an amber MURFI linker, 5'CTAG TCTAGA CTAG3' to disrupt the lacZ gene, yielding truncated beta-galactosidase proteins. Conditional disruption of the tetr gene in E. coli has also been demonstrated. Nonsense codon MURFI linkers permit conditional fusion of multiple gene products while sense codon linkers can add structural elements (e.g. beta-turn, cationic segment, hydrophobic segment) or a desired amino acid to a protein (e.g. methionine, cysteine). Shotgun or alternatively site-directed insertion of the symmetric linkers is possible. The over-all length of the linker may be adjusted to retain the original reading frame, matching nucleotide additions or subtractions at recipient DNA sites. If a linker restriction site occurs elsewhere in the target DNA, single linker copies may still be inserted using non-phosphorylated linkers.     

Optimized linker sequences for the expression of monomeric and dimeric bispecific single-chain diabodies.

Bispecific single-chain diabodies (scDb) consist of the variable heavy and light chain domains of two antibodies connected by three linkers. The structure of an scDb in the V(H)-V(L) orientation is V(H)A-linkerA-V(L)B-linkerM-V(H)B-linkerB-V(L)A, with linkers A and B routinely chosen to be 5-6 residues and linker M 15-20 residues. Here, we applied display of scDb on filamentous phage to analyse the composition of optimal linker sequences. The three linkers were randomized in length and sequence using degenerated triplets coding for only six hydrophilic or aliphatic amino acids (Thr, Ser, Asp, Asn, Gly, Ala). Antigen-binding clones were then isolated by one to two rounds of selection on the two different antigens recognized by the bispecific scDb. Using an scDb directed against carcinoembryonic antigen (CEA) and beta-galactosidase (Gal), we found that monomeric scDb had a preferred length of 15 or more amino acid residues for the middle linker M and of 3-6 residues for the linkers A and B. No obvious bias towards a preferred linker sequence was observed. Reduction of the middle linker below 13 residues led to the formation of dimeric scDb, which most likely results from interchain pairing between all the V(H) and V(L) domains. Dimeric scDb were also formed by fragments possessing a long linker M and linkers A and B of 0 or 1 residue. We assume that these dimeric scDb are formed by intrachain pairing of the central variable domains and interchain pairing of the flanking variable domains. Thus, the latter molecules represent a novel format of bispecific and tetravalent molecules. The described strategy allows for the isolation of both optimized and minimal linker sequences for the assembly of monomeric or dimeric single-chain diabodies.     

Probing conservation of HAMP linker structure and signal transduction mechanism through analysis of hybrid sensor kinases

The HAMP linker, a predicted structural element observed in many sensor kinases and methyl-accepting chemotaxis proteins, transmits signals between sensory input modules and output modules. HAMP linkers are located immediately inside the cytoplasmic membrane and are predicted to form two short amphipathic alpha-helices (AS-1 and AS-2) joined by an unstructured connector. HAMP linkers are found in the Escherichia coli nitrate- and nitrite-responsive sensor kinases NarX and NarQ (which respond to ligand by increasing kinase activity) and the sensor kinase CpxA (which responds to ligand by decreasing kinase activity). We constructed a series of hybrids with fusion points throughout the HAMP linker, in which the sensory modules of NarX or NarQ are fused to the transmitter modules of NarX, NarQ, or CpxA. A hybrid of the NarX sensor module and the CpxA HAMP linker and transmitter module (NarX-CpxA-1) responded to nitrate by decreasing kinase activity, whereas a hybrid in which the HAMP linker of NarX was replaced by that of CpxA (NarX-CpxA-NarX-1) responded to nitrate by increasing kinase activity. However, sequence variations between HAMP linkers do not allow free exchange of HAMP linkers or their components. Certain deletions in the NarX HAMP linker resulted in characteristic abnormal responses to ligand; similar deletions in the NarQ and NarX-CpxA-1 HAMP linkers resulted in responses to ligand generally similar to those seen in NarX. We conclude that the structure and action of the HAMP linker are conserved and that the HAMP linker transmits a signal to the output domain that ligand is bound.     

Conformations of variably linked chimeric proteins evaluated by synchrotron X-ray small-angle scattering

We constructed chimeric proteins that consist of two green fluorescent protein variants, EBFP and EGFP, connected by flexible linkers, (GGGGS)n (n = 3 approximately 4), and helical linkers, (EAAAK)n (n = 2 approximately 5). The conformations of the chimeric proteins with the various linkers were evaluated using small-angle X-ray scattering (SAXS). The SAXS experiments showed that introducing the short helical linkers (n = 2 approximately 3) causes multimerization, while the longer linkers (n = 4 approximately 5) solvate monomeric chimeric proteins. With the moderate-length linkers (n = 4), the observed radius of gyration (R(g)) and maximum dimension (D(max)) were 38.8 A and 120 A with the flexible linker, and 40.2 A and 130 A with the helical linker, respectively. The chimeric protein with the helical linker assumed a more elongated conformation as compared to that with the flexible linker. When the length of the helical linker increased (n = 5), R(g) and D(max) increased to 43.2 A and 140 A, respectively. These results suggest that the longer helix effectively separates the two domains of the chimeric protein. Considering the connectivity of the backbone peptide of the protein, the helical linker seems to connect the two domains diagonally. Surprisingly, the chimeric proteins with the flexible linker exhibited an elongated conformation, rather than the most compact side-by-side conformation expected from the fluorescence resonance energy transfer (FRET) analysis. Furthermore, the SAXS analyses suggest that destabilization of the short helical linker causes multimerization of the chimeric proteins. Information about the global conformation of the chimeric protein is thus be necessary for optimization of the linker design.     

Co-evolution of base composition and codon usage in Xenopus laevis and human globin genes with long-range DNA organization of their genome

Eucaryotic DNA is punctuated by many A+T-rich segments that we named A+T-rich linkers. Two types of these A+T-rich linkers can be distinguished: (i) isolated A+T-rich linkers, and (ii) A+T-rich linkers crowded in clusters. We have analysed the distribution of A+T-rich linker across the alpha- and beta-globin gene domain in Xenopus laevis and human genomes using isodenaturation and electron microscopy. Comparison of our data with those previously obtained for the avian globin genes leads us to conclude that genes can be harboured indifferently in either domain. A correlation is established between the presence of A+T-rich linker inside introns and flanking regions and the A+T content of the coding sequence. For the coding sequence, a high A+T content is strongly correlated with high A+T content in the codon's third position and weakly in the first position.     

Enzymatic labeling of a single chain variable fragment of an antibody with alkaline phosphatase by microbial transglutaminase

Functional cross-linking of a single chain Fv fragment of anti-hen egg-white lysozyme antibody (scFv) and alkaline phosphatase (AP) was explored using microbial transglutaminase (MTG) from Streptomyces mobaraensis. A specific peptidyl linker for MTG was genetically fused to the N-terminus of each protein and the resultant proteins were obtained separately by bacterial expression. The recombinant peptide-tagged scFv and AP were site-specifically cross-linked by MTG through the extra peptidyl linkers in vitro, which mainly yielded the heterodimer (i.e., scFv-AP conjugate). The enzymatic cross-linking reaction had little influence on either the antigen-binding ability of the scFv moiety or the enzymatic activity of the AP moiety of the conjugate, allowing use within an enzyme-linked immunosorbent assay. The results obtained suggest that the enzymatic approach with MTG facilitates the posttranslational construction of functional fusion proteins.     

Stable linker peptides for a cellulose-binding domain-lipase fusion protein expressed in Pichia pastoris.

Fusion proteins composed of a cellulose-binding domain from Neocallimastix patriciarum cellulase A and Candida antarctica lipase B were constructed using different linker peptides. The aim was to create proteolytically stable linkers that were able to join the functional modules without disrupting their function. Six fusion variants containing linkers of 4-44 residues were expressed in Pichia pastoris and analysed. Three variants were found to be stable throughout 7-day cultivations. The cellulose-binding capacities of fusion proteins containing short linkers were slightly lower compared with those containing long linkers. The lipase-specific activities of all variants, in solution or immobilized on to cellulose, were equal to that of the wild-type lipase.