Cloning and expression of the pneumococcal autolysin gene in Escherichia coli

Summary A 7.5 kb BclI-fragment of Streptococcs pneumoniae DNA has been cloned in Escherichia coli HB101 using pBR322 as a vector. The new plasmid (pGL30) of 12.0 kb expresses a protein that has been characterized by biochemical, immunological and genetic methods as the inactive form (E-form) of the pneumococcal N-acetyl-muramyl-l-alanyl amidase (EC 3.5.1.28). Our results demonstrate that the E-form is the primary product of the lyt gene of S. pneumoniae. The inactive E-form can be converted to the active C-form in vitro by incubation of the E-form enzyme with choline-containing pneumococcal cell walls at low temperature in a similar way to enzyme production in the homologous system. The production of this protein in E. coli HB101 was 500-fold higher than in the homologous host. E. coli CSR603 containing pGL30 and labeled with [³⁵S]methionine synthesized a 35 kd protein. pGL30 can transform at high frequency an autolysin-defective mutant of S. pneumoniae to the lyt⁺ phenotype.     

Reconsideration of the taxonomy of ellipsoidal species of Chlorella (Trebouxiophyceae, Chlorophyta), with establishment of Watanabea sen. nov.

Subcultures of SAG 211–9b and 1AM C-211, ultimately derived from CCAP 211/9b, a strain isolated by Pringsheim in 1939 and identified as Chlorella sac-charophila (Kruger) Migula were observed using light and electron microscopy. Their morphology proved to be basically identical. Both have two forms of cells, one (E-form) narrowly to broadly ellipsoidal, the other (S-form) ovoid to spheroidal. The cell wall of both forms is composed of a single smooth layer. The chloroplast of young cells is trough-like or saucer-shaped with a smooth margin, while that of mature cells is band- or cup-shaped with deep incisions. The thylakoid lamellae are loosely stacked and neither form has a pyrenoid. Both types of cells are capable of producing autospores: eight to 16 in E-form cells, two to four in S-form cells. These morphological features are different from those of C. saccharophila, which has a pyrenoid and produces only one form of autospores. In the absence of any existing genus that includes Chlorella-like algae with a simple cell wall, no pyrenoid, and two forms of mature cells and autospores, a new genus, Watanabea, is proposed with the type species W. reniformis.     

The dynamics of interconverting D- and E-forms of the HIV-1 integrase N-terminal domain

The N-terminal domain (NTD) of HIV-1 integrase adopts two inter-converting forms (D- and E-) due to their specific coordination of a Zn²⁺ ion by an HHCC motif. Mutational studies on NTD have suggested the importance of conformational transition in regulating the functions of tetramers and dimers of HIV-1 integrase. This study explores the stability and dynamics of native NTD forms and the conformational transition between D- and E-forms using molecular dynamics simulations elucidating their role in regulation of viral and host DNA integration. Simulation of native forms of NTD revealed stable dynamics. Transition studies between D- and E-forms using conventional molecular dynamics simulations for 50 ns partially revealed conformational change towards the target during D- to -E simulation (the extension of α1-helix), which failed in the E- to -D simulation. This could be attributed to the existence of the D-form (?1,945.907 kCal/mol) in higher energy than the E-form (?2,002.383 kCal/mol). The conformational transition pathway between these two states was explored using targeted molecular dynamics simulations. Analysis of the targeted molecular dynamics trajectories revealed conformations closer to the experimentally-reported intermediate form of an NTD during the transition phase. The role of Met22 in stabilizing the E-form was studied by simulating the E-form with Met22Ala mutation, revealing a highly dynamic α1-helix as compared to the native form. The present study reveals the significant role of the Zn²⁺ ion-coordinated HHCC motif and its interaction with Met22 as the basis for understanding the biological implications of D- and E-forms of the NTD in regulating integration reaction.     

Chemical modification of bovine liver rhodanese with tetrathionate: differential effects on the sulfur-free and sulfur-containing catalytic intermediates

Sulfhydryl groups of bovine liver rhodanese (thiosulfate: cyanide sulfurtransferase, EC 2.8.1.1) were modified by treatment with tetrathionate. There was a linear relationship between loss of enzyme activity and the amount of tetrathionate used. At a ratio of one tetrathionate per mole of rhodanese, 100% of enzyme activity was lost in the sulfur-free E-form as compared with a 70% loss for the sulfur-containing ES-form of the enzyme. Addition of up to a 100-fold molar excess of tetrathionate to ES gave no further inactivation. Addition of cyanide to the maximally inactivated ES-tetrathionate complex gave complete loss of activity. Kinetic studies of maximally inactivated ES and partially inactivated E gave Km (Ks) values that were essentially the same as native enzyme, indicating that the active enzyme, in all cases, bound thiosulfate similarly. Reactivation was faster with the ES-form than with the E-form. The substrate, thiosulfate, could reactivate the enzyme up to 70% in 1 h with ES as compared to 24 h with E. Tetrathionate modification of rhodanese could be correlated with the changes in intrinsic fluorescence and with the binding of the active site reporter 2-anilinonaphthalene-8-sulfonic acid (2,8-ANS). Circular dichroism spectra of the protein suggested increased ordered secondary structure in the protein after reaction with tetrathionate. Cadmium chloride and phenylarsine oxide totally inactivated the enzyme at levels usually associated with their effect on enzymes containing vicinal sulfhydryl groups. Further, cadmium inhibition could be reversed by EDTA. Tetrathionate modification of rhodanese may proceed through the formation of sulfenylthiosulfate intermediates at sulfhydryl groups, close to but not identical with the active-site sulfhydryl group, which then can react further with the active-site sulfhydryl group to form disulfide bridges.     

Chemical modification of bovine liver rhodanese with tetrathionate: differential effects or the sulfur-free and sulfur-containing catalytic intermediates

Sulfhydryl groups of bovine liver rhodanese (thiosulfate: cyanide sulfurtransferase, EC 2.8.1.1) were modified by treatment with tetrathionate. There was a linear relationship between loss of enzyme activity and the amount of tetrathionate used. At a ratio of one tetrathionate per mole of rhodanese, 100% of enzyme activity was lost in the sulfur-free E-form as compared with a 70% loss for the sulfur-containing ES-form of the enzyme. Addition of up to a 100-fold molar excess of tetrathionate to ES gave no further inactivation. Addition of cyanide to the maximally inactivated ES-tetrathionate complex gave complete loss of activity. Kinetic studies of maximally inactivated ES and partially inactivated E gave K_m (K₅) values that were essentially the same as native enzyme, indicating that the active enzyme, in all cases, bound thiosulfate-similarly. Reactivation was faster with the ES-form than with the E-form. The substrate, thiosulfate, could reactivate the enzyme up to 70% in 1 h with ES as compared to 24 h with E. Tetrathionate modification of rhodanese could be correlated with the changes in intrinsic fluorescence and with the binding of the active site reporter 2-anilinonaphthalene-8-sulfonic acid (2,8-ANS). Circular dichroism spectra of the protein suggested increased ordered secondary structure in the protein after reaction with tetrathionate. Cadmium chloride and phenylarsine oxide totally inactivated the enzyme at levels usually associated with their effect on enzymes containing vicinal sulfhydryl groups. Further, cadmium inhibition could be reserved by EDTA. Tetrathionate modification of rhodanese may proceed through the formation of sulfenylthiosulfate intermediates at sulfhydryl groups, close to but not identical with the active-site sulfhydryl group, which then can react further with the active-site sulfhydryl group to form disulfide bridges.     

Photoisomerization of 2-[3-(2-thioxopyrrolidin-3-ylidene)methyl]-tryptophan, a yellow pigment in salted radish roots

The photostability of (E)-2-[3-(2-thioxopyrrolidin-3-ylidene)methyl]-tryptophan ((E)-TPMT), the main yellow pigment in salted radish, was studied. First we analyzed the photoproduct generated from (E)-TPMT under longwave UV irradiation. On the basis of NMR spectroscopy, the photoproduct was identified as Z-configurated TPMT, and isomerization from the Z- to the E-form was reversibly induced by Vis-light irradiation. The optimum wavelength for isomerization from the E- to the Z-form was 360-380 nm, and that for isomerization from the Z- to the E-form was 440-460 nm. The E/Z-ratios in the photostationary state under UV- and Vis-light irradiation conditions were approximately 0.95:1 and 26:1 respectively. The (Z)-isomer was more sensitive to light irradiation than the (E)-isomer in the quantum yield measurement. Yellowing was dependent on the ratio of the (Z)-isomer, because the b(*) and chroma value rose with increases in the (Z)-isomer by the colorimeters. Hence, it is possible that the formation of the (Z)-isomer contribute to the yellow color of takuan-zuke during long salting and fermentation.     

Large-scale production,purification, and characterisation of recombinant Phaseolus vulgaris phytohemagglutinin E-form expressed in the methylotrophic yeast Pichia pastoris

The kidney bean lectin Phaseolus vulgaris phytohemagglutinin E-form (PHA-E) was expressed and secreted by the methylotrophic yeast Pichia pastoris. To optimise yields of PHA-E, transformants of P. pastoris were selected for high-level production of the recombinant protein. A scaleable process for the production and purification of gram quantities of recombinant PHA-E is reported. PHA-E was secreted at approximately 100 mg/L at the 2- and 200-L scale and was purified to 95% homogeneity in a single step using cation-exchange chromatography. The purified recombinant PHA-E consists of four forms with molecular masses between 28.5 and 31.5 kDa, as assessed by MALDI-TOF, whereas its native counterpart has a molecular mass of approximately 30.5 kDa. Endoglycosidase treatment revealed that the range in size of the recombinant protein was attributed to differences in the nature of the N-linked oligosaccharides bound to the protein. The primary amino acid sequence of the recombinant PHA-E was found to be identical to the native protein and to have an agglutination activity similar to that of native PHA-E. The data presented here suggest that, using P. pastoris, gram quantities of a recombinant phytohemagglutinin E-form can be produced and that the recombinant protein is similar to the protein synthesised in plants with respect to structure and biological activity.     

Unprecedented olefin-dependent histidine-kinase inhibitory of zerumbone ring-opening material

Zerumbone ring-opening derivative, 4 (10E/10Z=3/2), inhibited autophosphorylation of the essential histidine-kinase YycG existing in Bacillus subtilis constituting a two-component system (TCS). Generation of 4E-form could be regulated chemically using the difference from the ring-opening reactivity of the precursor forming of 4 and pure 4E was isolated. The stereoisomer, 4E, showed main inhibition activity of autophosphorylation of YycG (IC(50)=63.5 microM).     

Characterization of LytA-like N-acetylmuramoyl-L-alanine amidases from two new Streptococcus mitis bacteriophages provides insights into the properties of the major pneumococcal autolysin

Two new temperate bacteriophages exhibiting a Myoviridae (phiB6) and a Siphoviridae (phiHER) morphology have been isolated from Streptococcus mitis strains B6 and HER 1055, respectively, and partially characterized. The lytic phage genes were overexpressed in Escherichia coli, and their encoded proteins were purified. The lytAHER and lytAB6 genes are very similar (87% identity) and appeared to belong to the group of the so-called typical LytA amidases (atypical LytA displays a characteristic two-amino-acid deletion signature). although they exhibited several differential biochemical properties with respect to the pneumococcal LytA, e.g., they were inhibited in vitro by sodium deoxycholate and showed a more acidic pH for optimal activity. However, and in sharp contrast with the pneumococcal LytA, a short dialysis of LytAHER or LytAB6 resulted in reversible deconversion to the low-activity state (E-form) of the fully active phage amidases (C-form). Comparison of the amino acid sequences of LytAHER and LytAB6 with that of the pneumococcal amidase suggested that Val317 might be responsible for at least some of the peculiar properties of S. mitis phage enzymes. Site-directed mutagenesis that changed Val317 in the pneumococcal LytA amidase to a Thr residue (characteristic of LytAB6 and LytAHER) produced a fully active pneumococcal enzyme that differs from the parental one only in that the mutant amidase can reversibly recover the low-activity E-form upon dialysis. This is the first report showing that a single amino acid residue is involved in the conversion process of the major S. pneumoniae autolysin. Our results also showed that some lysogenic S. mitis strains possess a lytA-like gene, something that was previously thought to be exclusive to Streptococcus pneumoniae. Moreover, the newly discovered phage lysins constitute a missing link between the typical and atypical pneumococcal amidases known previously.     

Conformationally restricted anti-plasmodial chalcones

Chalcones can exist as Z- or E-isomers and it is generally anticipated that both isomers are equipotent. In order to determine the active isomer of anti-plasmodial chalcones a series of analogues locked in the Z- or the E-form were prepared and evaluated for their anti-plasmodial activity. It was shown that the Z-locked analogue was nearly inactive, whereas the E-locked analogues were equipotent to the parent chalcones, indicating that the E-isomer is the active conformation.     

Amide isosteres of lexitropsins: synthesis, DNA binding characteristics and sequence selectivity of thioformyldistamycin.

The synthesis and properties of an amide isostere of the antibiotic distamycin, thioformyldistamycin 3 is described. Compound 3 exists predominantly in the E conformation of the thioamide group in freshly prepared DMSO solution but is converted into the Z form, predicted by molecular mechanics to be more stable, on standing for 24 h. The coalescence temperature in DMSO is 110 degrees C by 1H-NMR. The thioformyl moiety of 3 is resistant to both peptidase action and acid treatment. Complementary strand MPE footprinting on a EcoRI/Hind III restriction fragment of pBR322 DNA demonstrated that either E or Z forms of 3 give a single set of footprints very similar to that of the parent antibiotic with strongest protection at TAAG and TATTAT with moderately strong protection at ATTT and AAAA. The strength of binding of 3 and distamycin from delta Tm measurements to either poly.d(AT) or calf thymus DNA is comparable. Molecular modeling predicted a preferred conformation for 3 wherein the C = S bond has a torsional angle of 110 degrees with the pyrrole ring. The energy difference between this conformation and the E form is less than 1 kcal/mole. In contrast the E-form has an energy 17.3 kcal/mole greater than the Z and a value of 26.3 kcal/mole was calculated for the energy barrier between the two isomers.     

Interaction of the pneumococcal amidase with lipoteichoic acid and choline

The choline-containing lipoteichoic acid (LTA, Forssman Antigen) of Streptococcus pneumoniae suppresses the activity of the pneumococcal autolysin, an N-acetyl-muramoyl-L-alanine-amidase (amidase) in aqueous solution [H?ltje and Tomasz (1975) Proc. Natl Acad. Sci. USA 72, 1690-1694]. The interaction between LTA and enzyme was used to establish a purification by affinity chromatography on LTA-Sepharose. The amidase could be eluted from the column with choline only. This implies that binding of the enzyme to LTA is mediated via the choline residues of the LTA. Upon binding to the LTA-Sepharose, the amidase converted from the applied E-form (an inactive form of the amidase) to the active C-form, a process which up to now was known to be mediated only by the pneumococcal choline-containing wall teichoic acid. Similar interactions between LTA and amidase seemed to occur in membrane fractions derived from choline-grown cells: the membrane-associated enzyme was present in the C-form and could be detached completely with choline, suggesting that the amidase is bound to the membrane attached LTA rather than being a membrane protein itself. This was supported by the absence of amidase activity in membrane fractions derived from ethanolamine-grown pneumococci, in which choline containing LTA is absent. The LTA-Sepharose-associated amidase was not inhibited, but retained its activity. The enzyme was also not inhibited by lipase-digested LTA. Both are conditions where the LTA is not present in micelles, unlike in aqueous solution. Therefore, mere binding to the LTA is probably not responsible for the inhibitory effect, but inhibition is a manifestation of an inaccessibility of the substrate for the amidase when bound to micellar LTA. When the interactions between choline and amidase were investigated, it was found that high choline concentrations (2%) inhibited the enzyme completely. Even in vivo, 2% choline in the culture medium led to phenotypically amidase-deficient pneumococci. Furthermore, in vitro, low choline concentrations (0.1%) suppressed the wall-mediated conversion. On the other hand, with high choline concentrations (2%) conversion took place in the absence of cell walls. Depending on how the amidase has been converted, the apparent Mr of the resulting C-amidase was different: the cell-wall-converted enzyme was of high Mr, whereas the choline-converted and the LTA-Sepharose-eluted enzyme showed an apparent low molecular mass known for the E-form, when analyzed on sucrose gradients.(ABSTRACT TRUNCATED AT 400 WORDS)     

Morphological variation in <Emphasis Type="Italic">Laboulbenia polymorpha</Emphasis> (Laboulbeniales)

Specimens of the type collection of Laboulbenia polymorpha Sugiyama (1978) were reexamined. The holotype, M. Ishikawa 673, is composed of three slides and includes three morphologically different forms of thalli, of which two forms were illustrated (Sugiyama 1978, fig. 1-D, 1-E). On the other hand, one of the paratypes, M. Ishikawa 674, has now been lost but photographs were made earlier from this slide, in which one mature individual illustrated as fig. 1-C (Sugiyama 1978) is included. This individual was not correctly shown in Sugiyamas illustration, but actually has a strong resemblance to a form in slide 673-b that was not illustrated by Sugiyama (1978). Thus, three different forms have been recognized as variations of L. polymorpha. In the present article, each variation was termed C-form, D-form, and E-form because Sugiyama (1978) used the same notation in his figures. A mature specimen of C-form in slide 673-b has been selected as a lectotype. Slide 673-d includes only young thalli, one of which was illustrated as fig. 1-G (Sugiyama 1978). This young thallus undoubtedly belongs to another species; mature thalli of the same species were also found in slide 673-b. Another paratype, K. Sugiyama 2101, includes C- and D-forms of L. polymorpha. Infection sites of the C- and D-forms have been determined: the C-form grows mainly on the lateral margins of the elytra of the host, and the D-form occurs mainly on the basal part of the elytra and the mesothorax.     

Key role of amino acid residues in the dimerization and catalytic activation of the autolysin LytA, an important virulence factor in Streptococcus pneumoniae

LytA, the main autolysin of Streptococcus pneumoniae, was the first member of the bacterial N-acetylmuramoyl-l-alanine amidase (NAM-amidase) family of proteins to be well characterized. This autolysin degrades the peptidoglycan bonds of pneumococcal cell walls after anchoring to the choline residues of the cell wall teichoic acids via its choline-binding module (ChBM). The latter is composed of seven repeats (ChBRs) of approximately 20 amino acid residues. The translation product of the lytA gene is the low-activity E-form of LytA (a monomer), which can be "converted" (activated) in vitro by choline into the fully active C-form at low temperature. The C-form is a homodimer with a boomerang-like shape. To study the structural requirements for the monomer-to-dimer modification and to clarify whether "conversion" is synonymous with dimerization, the biochemical consequences of replacing four key amino acid residues of ChBR6 and ChBR7 (the repeats involved in dimer formation) were determined. The results obtained with a collection of 21 mutated NAM-amidases indicate that Ile-315 is a key amino acid residue in both LytA activity and folding. Amino acids with a marginal position in the solenoid structure of the ChBM were of minor influence in dimer stability; neither the size, polarity, nor aromatic nature of the replacement amino acids affected LytA activity. In contrast, truncated proteins were drastically impaired in their activity and conversion capacity. The results indicate that dimerization and conversion are different processes, but they do not answer the questions of whether conversion can only be achieved after a dimer formation step.     

Transient state kinetic studies of the MutT-catalyzed nucleoside triphosphate pyrophosphohydrolase reaction

The MutT pyrophosphohydrolase, in the presence of Mg2+, catalyzes the hydrolysis of nucleoside triphosphates by nucleophilic substitution at Pbeta, to yield the nucleotide and PP(i). The best substrate for MutT is the mutagenic 8-oxo-dGTP, on the basis of its Km being 540-fold lower than that of dGTP. Product inhibition studies have led to a proposed uni-bi-iso kinetic mechanism, in which PP(i) dissociates first from the enzyme-product complex (k3), followed by NMP (k4), leaving a product-binding form of the enzyme (F) which converts to the substrate-binding form (E) in a partially rate-limiting step (k5) [Saraswat, V., et al. (2002) Biochemistry 41, 15566-15577]. Single- and multiple-turnover kinetic studies of the hydrolysis of dGTP and 8-oxo-dGTP and global fitting of the data to this mechanism have yielded all of the nine rate constants. Consistent with an "iso" mechanism, single-turnover studies with dGTP and 8-oxo-dGTP hydrolysis showed slow apparent second-order rate constants for substrate binding similar to their kcat/Km values, but well below the diffusion limit (approximately 10(9) M(-1) s(-1)): k(on)app = 7.2 x 10(4) M(-1) s(-1) for dGTP and k(on)app = 2.8 x 10(7) M(-1) s(-1) for 8-oxo-dGTP. These low k(on)app values are fitted by assuming a slow iso step (k5 = 12.1 s(-1)) followed by fast rate constants for substrate binding: k1 = 1.9 x 10(6) M(-1) s(-1) for dGTP and k1 = 0.75 x 10(9) M(-1) s(-1) for 8-oxo-dGTP (the latter near the diffusion limit). With dGTP as the substrate, replacing Mg2+ with Mn2+ does not change k1, consistent with the formation of a second-sphere MutT-M2+-(H2O)-dGTP complex, but slows the iso step (k5) 5.8-fold, and its reverse (k(-5)) 25-fold, suggesting that the iso step involves a change in metal coordination, likely the dissociation of Glu-53 from the enzyme-bound metal so that it can function as the general base. Multiple-turnover studies with dGTP and 8-oxo-dGTP show bursts of product formation, indicating partially rate-limiting steps following the chemical step (k2). With dGTP, the slow steps are the chemical step (k2 = 10.7 s(-1)) and the iso step (k5 = 12.1 s(-1)). With 8-oxo-dGTP, the slow steps are the release of the 8-oxo-dGMP product (k4 = 3.9 s(-1)) and the iso step (k5 = 12.1 s(-1)), while the chemical step is fast (k2 = 32.3 s(-1)). The transient kinetic studies are generally consistent with the steady state kcat and Km values. Comparison of rate constants and free energy diagrams indicate that 8-oxo-dGTP, at low concentrations, is a better substrate than dGTP because it binds to MutT 395-fold faster, dissociates 46-fold slower, and has a 3.0-fold faster chemical step. The true dissociation constants (KD) of the substrates from the E-form of MutT, which can now be obtained from k(-1)/k1, are 3.5 nM for 8-oxo-dGTP and 62 microM for dGTP, indicating that 8-oxo-dGTP binds 1.8 x 10(4)-fold tighter than dGTP, corresponding to a 5.8 kcal/mol lower free energy of binding.     

The C-terminal sequence of LMADS1 is essential for the formation of homodimers for B function proteins

LMADS1, a lily (Lilium longiflorum) AP3 orthologue, contains the complete consensus sequence of the paleoAP3 (YGSHDLRLA) and PI-derived (YEFRVQPSQPNLH) motifs in the C-terminal region of the protein. Interestingly, through yeast two-hybrid analysis, LMADS1 was found to be capable of forming homodimers. These results indicated that LMADS1 represents an ancestral form of the B function protein, which retains the ability to form homodimers in regulating petal and stamen development in lily. To explore the involvement of the conserved motifs in the C-terminal region of LMADS1 in forming homodimers, truncated forms of LMADS1 were generated, and their ability to form homodimers was analyzed using yeast two-hybrid and electrophoretic mobility shift assay. The ability of LMADS1 to form homodimers decreased once the C-terminal paleoAP3 motif was deleted. When both paleoAP3 and PI-derived motifs were deleted, the ability of LMADS1 to form homodimers was completely abolished. This result indicated that although the paleoAP3 motif promotes the formation of LMADS1 homodimers, the PI-derived motif is essential. Deletion analysis indicated that two amino acids, RV, of the 5 final amino acids, YEFRV, in the PI-derived motif are essential for the formation of homodimers. Further, point mutation analysis indicated that amino acid Val was absolutely necessary, whereas residue Arg played a less important role in the formation of homodimers. Furthermore, Arabidopsis AP3 was able to form homodimers once its C-terminal region was replaced by that of LMADS1. This result indicated that the C-terminal region of LMADS1 is responsible and essential for homodimer formation of the ancestral form of the B function protein.     

Novel antibody hinge regions for efficient production of CH2 domain-deleted antibodies

HuCC49 deltaCH2 is a heavy chain constant domain 2 domain-deleted antibody under development as a radioimmunotherapeutic for treating carcinomas overexpressing the TAG-72 tumor antigen. Mammalian cell culture biosynthesis of HuCC49 deltaCH2 produces two isoforms (form A and form B) in an approximate 1:1 ratio, and consequently separation and purification of the desired form A isoform adversely impact process and yield. A protein engineering strategy was used to develop a panel of hinge-engineered HuCC49 deltaCH2 antibodies to identify hinge sequences to optimize production of the form A isoform. We found that adding a single proline residue at Kabat position 243, immediately adjacent to the carboxyl end of the core middle hinge CPPC domain, resulted in an increase from 39 to 51% form A isoform relative to the parent HuCC49 deltaCH2 antibody. Insertion of the amino acids proline-alanine-proline (PAP) at positions 243-245 enhanced production of the form A isoform to 72%. Insertion of a cysteine-rich 15-amino acid IgG3 hinge motif (CPEPKSCDTPPPCPR) in both of these mutant antibodies resulted in secretion of predominantly form A isoform with little or no detectable form B. Yields exceeding 98% of the form A isoform have been realized. Preliminary peptide mapping and mass spectrometry analysis suggest that at least two, and as many as five, inter-heavy chain disulfide linkages may be present.     

The Trypanosoma brucei cyclin, CYC2, is required for cell cycle progression through G1 phase and for maintenance of procyclic form cell morphology

CYC2 is an essential PHO80-like cyclin that forms a complex with the cdc2-related kinase CRK3 in Trypanosoma brucei. In both procyclic and bloodstream form T. brucei, knock-down of CYC2 by RNA interference (RNAi) led to an accumulation of cells in G(1) phase. Additionally, in procyclic cells, but not in bloodstream form cells, CYC2 RNAi induced a specific cell elongation at the posterior end. The G(1) block, as well as the posterior end elongation in the procyclic form, was irreversible once established. Staining for tyrosinated alpha-tubulin and morphometric analyses showed that the posterior end elongation occurred through active microtubule extension, with no repositioning of the kinetoplast. Hence, these cells can be classified as exhibiting the "nozzle" phenotype as has been described for cells that ectopically express TbZFP2, a zinc finger protein that is involved in the differentiation of the bloodstream form to procyclic form. Within the tsetse fly, procyclic trypanosomes differentiate to elongated mesocyclic cells. However, although mesocyclic trypanosomes isolated from tsetse flies also show active microtubule extension at the posterior end, the kinetoplast is coincidentally repositioned such that it always lies approximately midway between the nucleus and posterior end of the cell. Thus, in the procyclic form CYC2 has dual functionality and is required for both cell cycle progression through G(1) and for the maintenance of correct cell morphology, whereas in the bloodstream form only a role for CYC2 in G(1) progression is evident.     

Evidence for increased proton dissociation in low-activity forms of dephosphorylated squash-leaf nitrate reductase

The pH dependence of squash-leaf nitrate reductase has been studied. It has been found that high- and low-activity forms of purified nitrate reductase (both forms dephosphorylated) have different optimum pH values. A high-activity form has always a higher pH optimum compared with a low-activity form. Model computations show that the decrease in activity and the corresponding change of the pH optimum is apparently due to a conformation-dependent increase of proton dissociation of the enzyme. As previously shown, this behavior is also observed in leaf extracts during the conversion (and probably phosphorylation of nitrate reductase) from a high-active form to a low-active form when plants are transferred from light to darkness.