Engineering a reversible, high-affinity system for efficient protein purification based on the cohesin-dockerin interaction

Efficient degradation of cellulose by the anaerobic thermophilic bacterium, Clostridium thermocellum, is carried out by the multi-enzyme cellulosome complex. The enzymes on the complex are attached in a calcium-dependent manner via their dockerin (Doc) module to a cohesin (Coh) module of the cellulosomal scaffoldin subunit. In this study, we have optimized the Coh-Doc interaction for the purpose of protein affinity purification. A C. thermocellum Coh module was thus fused to a carbohydrate-binding module, and the resultant fusion protein was applied directly onto beaded cellulose, thereby serving as a non-covalent "activation" procedure. A complementary Doc module was then fused to a model protein target: xylanase T-6 from Geobacillus stearothermophilus. However, the binding to the immobilized Coh was only partially reversible upon treatment with EDTA, and only negligible amounts of the target protein were eluted from the affinity column. In order to improve protein elution, a series of truncated Docs were designed in which the calcium-coordinating function was impaired without appreciably affecting high-affinity binding to Coh. A shortened Doc of only 48 residues was sufficient to function as an effective affinity tag, and highly purified target protein was achieved directly from crude cell extracts in a single step with near-quantitative recovery of the target protein. Effective EDTA-mediated elution of the sequestered protein from the column was the key step of the procedure. The affinity column was reusable and maintained very high levels of capacity upon repeated rounds of loading and elution. Reusable Coh-Doc affinity columns thus provide an efficient and attractive approach for purifying proteins in high yield by modifying the calcium-binding loop of the Doc module.     

Effect of Linker Length and Dockerin Position on Conversion of a Thermobifida fusca Endoglucanase to the Cellulosomal Mode

We have been developing the cellulases of Thermobifida fusca as a model to explore the conversion from a free cellulase system to the cellulosomal mode. Three of the six T. fusca cellulases (endoglucanase Cel6A and exoglucanases Cel6B and Cel48A) have been converted in previous work by replacing their cellulose-binding modules (CBMs) with a dockerin, and the resultant recombinant “cellulosomized” enzymes were incorporated into chimeric scaffolding proteins that contained cohesin(s) together with a CBM. The activities of the resultant designer cellulosomes were compared with an equivalent mixture of wild-type enzymes. In the present work, a fourth T. fusca cellulase, Cel5A, was equipped with a dockerin and intervening linker segments of different lengths to assess their contribution to the overall activity of simple one- and two-enzyme designer cellulosome complexes. The results demonstrated that cellulose binding played a major role in the degradation of crystalline cellulosic substrates. The combination of the converted Cel5A endoglucanase with the converted Cel48A exoglucanase also exhibited a measurable proximity effect for the most recalcitrant cellulosic substrate (Avicel). The length of the linker between the catalytic module and the dockerin had little, if any, effect on the activity. However, positioning of the dockerin on the opposite (C-terminal) side of the enzyme, consistent with the usual position of dockerins on most cellulosomal enzymes, resulted in an enhanced synergistic response. These results promote the development of more complex multienzyme designer cellulosomes, which may eventually be applied for improved degradation of plant cell wall biomass.In nature, some anaerobic cellulolytic bacteria produce cellulosomes, which are organized by the action of scaffoldin subunits that usually contain a single carbohydrate-binding module (CBM) and multiple cohesin modules (2, 7, 13, 14, 28, 36). This arrangement allows the integration of several dockerin-containing enzymes into a complex, which is then targeted to the cellulosic substrate by the common CBM. The cellulosomal enzymes then exhibit enhanced synergistic activity, presumably due to their spatial proximity and coordinated interaction. In contrast, the enzyme systems of aerobic bacteria and fungi comprise free (uncomplexed) enzymes, which differ from cellulosomal systems in that many of them contain their own CBM that delivers the individual catalytic module to the surface of the substrate (39, 41, 42).In previous work, we used the designer cellulosome concept (5) to construct unique minicellulosomes of defined content (16, 32, 33). In order to construct designer cellulosomes, chimeric scaffoldins have been prepared which contained two or more cohesins that matched the dockerins of the enzymes (native cellulosomal or dockerin-fused chimeras). Enzymes that contain dockerins that match the specificity of a scaffoldin-borne cohesin can then be selectively integrated into the designer cellulosome at a specified site. Cellulosomal enzymes containing either a native dockerin or a divergent dockerin can be inserted on different sites of a chimeric scaffoldin. Alternatively, a free, noncellulosomal enzyme can be included in designer cellulosomes by replacing its native CBM with a dockerin of choice. In some cases, designer cellulosomes displayed enhanced synergistic activity over the parallel free-enzyme system (15, 17). This increased activity was shown to be a function of both a substrate-targeting effect (contributed by the CBM on the chimeric scaffoldin) and the enzyme proximity effect, thus supporting the initial hypothesis.In recent studies, we have investigated the free-cellulase system of Thermobifida fusca for use in designer cellulosome systems. This aerobic thermophilic cellulolytic bacterium contains a limited set of six free cellulases, each composed of a catalytic module and a crystalline-cellulose binding family 2 CBM (CBM2) module on either the N or C terminus of the protein. T. fusca contains three endoglucanases (Cel5A, Cel6A, and Cel9B), two exocellulases (Cel6B and Cel48A), and one processive endoglucanase (Cel9A). Previously, we converted both family 6 cellulases and the family 48 exoglucanase from the free to the cellulosomal mode of action by replacing their native CBM2s with a dockerin module (11, 12). All three chimeric enzymes exhibited cellulose-degrading activity on both soluble and crystalline substrates. The results indicated that the family 48 exoglucanase appeared to be well adapted to the cellulosomal mode of action, whereas the family 6 exoglucanase is less appropriate for inclusion into cellulosomes. Indeed, family 48 cellulases have been found to be a major component in every native cellulosome thus far described, in contrast to the family 6 cellulases, which have been identified only in free-cellulase systems.An important feature of the free-acting fungal and bacterial cellulases is that they contain a linker segment, often rich in prolines and threonines, that connects the catalytic module to the CBM (37). The role of such flexible linkers is thought to ensure independent action of the adjacent functional modules, thus allowing progressive and efficient hydrolysis of cellulose by the catalytic modules (6, 9, 10, 20, 25-27, 34, 36, 38, 40). The present communication focuses on the effect of linker length and dockerin position (relative to the catalytic module) on enzymatic activity within a designer cellulosome. For this purpose we have employed the highly active family 5 endoglucanase Cel5A from T. fusca (21, 22, 29), which was converted to the cellulosomal mode by replacement of its CBM with a dockerin module. Chimeric dockerin derivatives were prepared on either the N or C terminus of the Cel5A catalytic module, separated by linker segments of different lengths. In most cases, binary designer cellulosomes, comprising the respective Cel5A chimera together with a Cel48A chimera, were shown to be more efficient on crystalline cellulosic substrates than the combination of the wild-type free enzymes.     

Amalgam, an axon guidance Drosophila adhesion protein belonging to the immunoglobulin superfamily: over-expression, purification and biophysical characterization

Amalgam, a multi-domain member of the immunoglobulin superfamily, possesses homophilic and heterophilic cell adhesion properties. It is required for axon guidance during Drosophila development in which it interacts with the extracellular domain of the transmembrane protein, neurotactin, to promote adhesion. Amalgam was heterologously expressed in Pichia pastoris, and the secreted protein product, bearing an NH₂-terminal His₆Tag, was purified from the growth medium by metal affinity chromatography. Size exclusion chromatography separated the purified protein into two fractions: a major, multimeric fraction and a minor, dimeric one. Two protocols to reduce the percentage of multimers were tested. In one, protein induction was performed in the presence of the zwitterionic detergent CHAPS, yielding primarily the dimeric form of amalgam. In a second protocol, agitation was gradually reduced during the course of the induction and antifoam was added daily to reduce the air/liquid interfacial foam area. This latter protocol lowered the percentage of multimer 2-fold, compared to constant agitation. Circular dichroism measurements showed that the dimeric fraction had a high β-sheet content, as expected for a protein with an immunoglobulin fold. Dynamic light scattering and sedimentation velocity measurements showed that the multimeric fraction displays a monodisperse distribution, with R_H = 16 nm. When co-expressed together with amalgam the ectodomain of neurotactin copurified with it. Furthermore, both purified fractions of amalgam were shown to interact with Torpedo californica acetylcholinesterase, a structural homolog of neurotactin.     

Maternal separation modulates short-term behavioral and physiological indices of the stress response

Early-life stress produces an anxiogenic profile in adulthood, presumably by activating the otherwise quiescent hypothalamic-pituitary-adrenal (HPA) axis during the vulnerable ‘stress hyporesponsive period’. While the long-term effects of such early-life manipulations have been extensively characterized, little is known of the short-term effects. Here, we compared the short-term effects of two durations of maternal separation stress and one unseparated group (US) on behavioral and physiological indices of the stress response in rat pups. Separations included 3 h on each of 12 days, from postnatal day (PND) 2 to 13 (MS2-13) and 3 days of daily, 6-h separation from PND11-13 (MS11-13). On PND14 (Experiment 1), both MS2-13 and MS11-13 produced marked reductions in freezing toward an adult male conspecific along with reduced levels of glucocorticoid type 2 (GR) and CRF type-1 (CRF₁) receptor mRNA in the hippocampus. Group MS2-13 but not MS11-13 produced deficits in stressor-induced corticosterone secretion, accompanied by reductions in body weight. Our results suggest that GR and/or CRF₁ levels, not solely the magnitude of corticosterone secretion, may be involved in the modulation of freezing. In a second experiment, we aimed to extend these findings by testing male and female separated and unseparated pups' unconditioned defensive behaviors to cat odor on PND26, and subsequent cue + context conditioning and extinction throughout postnatal days 27-32. Our results show that maternal separation produced reductions in unconditioned freezing on PND26, with MS2-13 showing stronger deficits than MS11-13. However, separation did not affect any other defensive behaviors. Furthermore, separated rats failed to show conditioned freezing, although they did avoid the no-odor block conditioned cue. There were no sex differences other than weight. We suggest that maternal separation may have produced these changes by disrupting normal development of hippocampal regions involved in olfactory-mediated freezing, not in mechanisms of learning and memory per se. These findings may have direct relevance for understanding the mechanisms by which early-life adverse experiences produce short-term and lasting psychopathologies.     

Tom20 Mediates Localization of mRNAs to Mitochondria in a Translation-Dependent Manner

mRNAs encoding mitochondrial proteins are enriched in the vicinity of mitochondria, presumably to facilitate protein transport. A possible mechanism for enrichment may involve interaction of the translocase of the mitochondrial outer membrane (TOM) complex with the precursor protein while it is translated, thereby leading to association of polysomal mRNAs with mitochondria. To test this hypothesis, we isolated mitochondrial fractions from yeast cells lacking the major import receptor, Tom20, and compared their mRNA repertoire to that of wild-type cells by DNA microarrays. Most mRNAs encoding mitochondrial proteins were less associated with mitochondria, yet the extent of decrease varied among genes. Analysis of several mRNAs revealed that optimal association of Tom20 target mRNAs requires both translating ribosomes and features within the encoded mitochondrial targeting signal. Recently, Puf3p was implicated in the association of mRNAs with mitochondria through interaction with untranslated regions. We therefore constructed a tom20Δ puf3Δ double-knockout strain, which demonstrated growth defects under conditions where fully functional mitochondria are required. Mislocalization effects for few tested mRNAs appeared stronger in the double knockout than in the tom20Δ strain. Taken together, our data reveal a large-scale mRNA association mode that involves interaction of Tom20p with the translated mitochondrial targeting sequence and may be assisted by Puf3p.mRNA localization to distinct cellular compartments is important for the efficiency and specificity of the translation process. Synthesis of proteins at their sites of action may decrease the likelihood of ectopic protein expression and facilitate assembly of large multiprotein complexes. Two general modes for mRNA localization are known. The first, which is common for endoplasmic reticulum (ER)-associated mRNAs, necessitates translation of a short region of the protein (the signal peptide). The signal is recognized by the signal recognition particle as it emerges from the ribosome exit tunnel, and the complex that includes the mRNA, ribosome, and signal recognition particle is targeted to the ER (18). As an outcome of this process, mRNAs that encode proteins destined for the ER and the secretory pathway are associated with this compartment (7). The second mode for mRNA localization occurs prior to translation and in many cases prevents initiation of protein synthesis. Sequences or structural elements of the mRNA are bound by RNA-binding proteins, and these interact with transport factors, which direct the mRNA to its destination (5, 35, 42). Genome-wide studies indicate that localization by either mode is a broad phenomenon that encompasses many mRNAs and various cellular destinations (6, 21, 32, 38). Interestingly, we along with others have recently shown that noncoding regions may also be involved in localization of ER-associated mRNAs (1, 26, 38), demonstrating that these two modes are not mutually exclusive.Most of the mitochondrial proteins are encoded in the nucleus and need to be imported into the organelle. Various in vitro and in vivo assays led to the widely accepted notion that import may occur posttranslationally, i.e., after the protein is fully synthesized in the cytosol (33). However, mounting evidence also supports a cotranslational import of proteins into the mitochondria. Specifically, polysomes were shown to be associated with the mitochondrial surface, and these translated a distinct set of proteins (12, 19, 20). Moreover, isolated mitochondria are associated with many different mRNAs that encode mitochondrial proteins (28, 46). Elements from both the coding region (the mitochondrial targeting signal [MTS]) and the 3′ untranslated region (UTR) were shown to be important for targeting of some of these mRNAs (4, 29). One model for localization suggests association of the nascent peptide chain (specifically, the N-terminal MTS) with receptors on the mitochondria, coupled to cotranslational insertion of the protein (24). As an outcome of this cotranslational mechanism, polysomal mRNAs become associated with the mitochondria, analogously to what is observed in the ER. However, experimental support for this hypothesis is currently lacking.Recently, Saint-Georges et al. (41) have shown a role for Puf3p in localization of many mRNAs to the mitochondria of Saccharomyces cerevisiae. Puf3p is associated with the mitochondria outer membrane (11), and its role is mediated through interaction with UTRs. This may suggest a translation-independent mode of action. Intriguingly, however, most Puf3 targets appeared to be mislocalized also after treatment with the translation inhibitor cycloheximide (CHX), suggesting that an active translation process is required for their asymmetric localization (41). Moreover, a large number of mRNAs that are not Puf3 targets appeared to be affected from treatments with the translation inhibitors puromycin and cycloheximide (41), further supporting the existence of an additional, translation-dependent mode of mRNA targeting to the mitochondria.The translocase of the mitochondrial outer membrane (TOM complex) is a multiprotein machinery which mediates the import of the vast majority of proteins into the mitochondria (36, 39). Its core protein (Tom40) forms a β-barrel structure and serves as the main component of the import pore. Tom20 is a peripheral component of the TOM complex that functions as a primary receptor for mitochondrial precursor proteins (15). It was hypothesized that protein receptors interact with the incoming polypeptide while it is translated, and this leads to a local increase in mRNA concentration (24). An open question is whether the TOM complex, through Tom20, interacts with polypeptides while they are translated and thereby leads to higher local concentrations of mRNAs near the mitochondria. To address this issue, we analyzed the effects of TOM20 deletion on mRNA association with mitochondrial fractions and the role of the MTS on mRNA localization. We also tested the interactions between Tom20 and Puf3. We found that Tom20 is involved in mitochondrial association of many mRNAs by a process that requires the MTS. Tom20 deletion affects the localization of Puf3p, and a strain with deletions of both Tom20 and Puf3 exhibits a growth defect under conditions that require mitochondrial optimal function.     

A molecular and structural analysis of the VH and VK regions of monoclonal antibodies bearing the A48 regulatory idiotype

The results presented in this paper explore the molecular basis for expression of the A48 regulatory Id (RI). A48 RI+ mAb derived from idiotypically manipulated mice molecularly resembled the A48 and UPC 10 prototypes of this system by utilizing a VHX24-Vk10 combination. Id expression by these antibodies was not restricted by a particular D region sequence, JH, or JK segment, but quantitative differences in Id expression were associated with utilization of different members of the VK10 germ-line gene families. The VL sequences of these A48 RI+ mAb has identified amino acid residues lying in four different idiotope-determining regions which may contribute to the structural correlate of this Id. A comparative sequence analysis of the VH regions of these VHX24 utilizing A48 RI+ mAb with several A48 RI+ mAb utilizing VHJ558 or VH7183 VH genes as well as a hybrid transfectoma antibody derived from two A48 RI-, VHJ558 utilizing hybridomas, all suggested that four nonconsecutive positions which lie outside the idiotope-determining regions may contribute structural elements toward expression of this Id. The VH and VL regions of the A48RI+, VHX24-Vk 10+ mAb showed low to moderate levels of somatic mutation which showed different patterns of distribution between the complementary determining region (CDR) and framework regions in the H and L chains. Although the VK sequences contained 50% of the replacement mutations in the CDR, with a replacement/silent mutation ratio of 10, the CDR of the VH sequences contained only 31% of the replacement mutations with a replacement/silent mutation ratio of 0.69.     

The construction of DNA molecules of figure-eight structure

Using DNA molecules to construct a structural scaffold for nanotechnology is largely accepted. In this article, we report on two methods for constructing a figure-eight structure of DNA molecules having a relatively high yield that could be used further as a scaffold for nanotechnology applications. In the first method, two plasmids were constructed that, on digestion with a restriction endonuclease producing nicks in the corresponding sites and after heating, produced complementary single-stranded sequences, enabling the plasmids to hybridize to each other and forming a figure-eight structure. The formation of the figure-eight structure was analyzed by restriction analysis and gel electrophoresis as well as by atomic force microscopy. The second method makes use of the bacteriophage M13 that is obtained as either a single- or double-stranded circular DNA molecule. Two M13 molecules harboring complementary sequences were constructed and produced a figure-eight structure on hybridization. The methods described here could be used further for the construction of nanoelectronic devices.     

Patterns of First Intercourse: A Survey Among Israeli Women

Seasonality among animals has an important function in breeding cycles. Research focusing on conception and coital activity in humans has called attention to the possible existence of circannual rhythms in human sexual activity. We studied the diurnal variations, seasonality and subjective sexual preference among young women in Israel-focusing on their first intercourse. The survey included 135 college students who completed a self-report questionnaire. Half of the subjects (50%) reported loss of virginity during the summer with an almost equal distribution among the other seasons. Over 85% of the subjects had their first intercourse either in the evening or at night. Subjective sexual – seasonal – preference was reported by 44.4% of the subjects but no correlation was found between the preferred season and actual loss of virginity; except for the autumn “preferers”. Our study supports previous research generalizing the sociological explanation for seasonality of the first intercourse.