Advancements in adenoviral based virotherapy for ovarian cancer

Ovarian cancer is a leading gynecologic malignancy with relatively grim survival statistics. There is a significant need for the development of new treatment options for this malignancy. The development of virotherapy as a treatment option for ovarian cancer has the potential to improve patient survival. Adenoviruses have multiple advantages as vectors for virotherapy including a well-understood structure and the ability to infect cells easily. We will outline the advances in virotherapy in the treatment of ovarian cancer, with particular attention directed toward adenoviral vectors.

The timing of normalization of CA-125 levels during primary chemotherapy is predictive of survival in patients with epithelial ovarian cancer

OBJECTIVE

To determine if the timing of normalization of CA-125 levels during primary chemotherapy for epithelial ovarian cancer (EOC) could predict survival.

METHODS

Patients who reached a complete clinical response for EOC with primary taxane/platinum-based chemotherapy were eligible. Patient demographics, chemotherapy administration, CA-125 levels, and survival outcomes were abstracted. Progression free survival (PFS), overall survival (OS), and platinum sensitivity (>6 months from chemotherapy completion) were compared to CA-125 levels during primary therapy.

RESULTS

262 patients who achieved a complete clinical response were identified. Patients who achieved normalization of CA-125 by 3rd cycle of chemotherapy were compared to patients who failed to achieve normalization by the 3rd cycle. Patients with early normalization demonstrated improved PFS (19 vs. 6 months; p<0.001), OS (48 vs. 27 months; p<0.001) and platinum sensitivity (78 vs. 22%; p<0.001). This survival advantage was maintained when patients were evaluated by debulking status. Additionally, when stratified by the specific cycle patients' achieved normalization, PFS ranged from 25 months after surgery to 2 months after 6th cycle (p<0.001). OS demonstrated a similar trend from 74 months to 22 months (p<0.001), while platinum sensitivity decreased from 72% to 24% (p<0.001). An average of 3.8 months in PFS and 8.6 months of OS was gained for each one-cycle improvement in CA-125 normalization.

CONCLUSION

Earlier normalization of CA-125 levels during primary chemotherapy for EOC predicts improvement in platinum sensitivity, PFS, and OS. This data provides prognostic information that may influence future decisions regarding chemotherapy and potentially earlier enrollment in treatment protocols.

An outpatient intraperitoneal chemotherapy regimen for advanced ovarian cancer

OBJECTIVES

To assess the feasibility, associated toxicities, and reasons for early cessation of an outpatient intraperitoneal (IP) chemotherapy regimen for treatment of advanced ovarian cancer following optimal cytoreductive surgery.

METHODS

Between January 2006 and December 2007, 42 patients with stages IIC-IV epithelial ovarian, tubal, or primary peritoneal cancer who had residual disease <1 cm after cytoreductive surgery were treated with an outpatient IP chemotherapy protocol. Patients received intravenous (IV) docetaxel 75 mg/m(2) and IP cisplatin 75-100 mg/m(2) on day 1, followed by IP paclitaxel 60 mg/m(2) on day 8, with the intent to treat patients every 21 days for 6 cycles of chemotherapy. Charts were abstracted for demographic, chemotherapy, and toxicity-related data.

RESULTS

The median age of the 42 patients was 59 years (range 33-70) and the majority of patients had epithelial ovarian cancer (80%), FIGO stage IIIC (83%), and papillary serous histology (74%). Of an intended 252 IP chemotherapy cycles, 172 (68%) were administered. Twenty-nine patients (69%) completed >or=4 cycles and 12 (29%) received all 6 IP cycles. Common grade 3/4 toxicities by patient included neutropenia (43%), infection (21.5%), and gastrointestinal effects (14%). There was one treatment-related death. Reasons for discontinuation were largely chemotherapy (43%) or port (37%) related.

CONCLUSIONS

With supportive measures, such as scheduled hydration and granulocyte colony-stimulating factors, outpatient administration of IP chemotherapy was feasible. This regimen resulted in few hospitalizations or treatment delays and demonstrated less toxicity than previously reported IP chemotherapy regimens. Port-related complications were a leading cause of IP chemotherapy discontinuation.

The effect of obesity on survival in patients with ovarian cancer

OBJECTIVE

Data has suggested obesity as an independent prognostic factor for lower survival in patients with epithelial ovarian cancer (EOC). We sought to determine if obesity portends a disadvantage to surgical outcomes at the time of initial surgery affecting survival.

METHODS

A retrospective chart review of patients diagnosed with EOC was performed. All patients underwent primary cytoreductive surgery followed by taxane/platinum-based chemotherapy. Patient demographics, surgicopathologic and survival data were evaluated. Patients were compared based on body mass index (BMI) (<30 vs. > or =30) and BMI strata (underweight, normal weight, overweight, obese and morbidly obese). Survival analyses were performed with the Kaplan Meier method and compared using the log rank test, chi(2) test, and Fischer's exact test.

RESULTS

304 patients were identified. 71 patients (23%) were obese (BMI>30). The groups were similar in regard to stage, grade, histology, and chemotherapy administered. In regard to surgical outcomes, no difference was seen in estimated blood loss (EBL), operating room (OR) time, or operative complications excluding wound complications. Optimal debulking rates were similar in obese and non-obese patients (52% vs. 51% respectively, p=0.88). There was no statistical difference in progression free survival (17 vs. 11 months) or overall survival (48 vs. 40 months) between the two groups or across BMI strata.

CONCLUSION

Although obesity has been reported as an independent prognostic factor for survival, this data demonstrates that survival rates are similar between obese and non-obese patients when optimal debulking statuses are the same. Therefore, maximal effort should be directed towards optimal debulking obese patients with EOC.

Chemotherapy-related myelosuppression as a marker of survival in epithelial ovarian cancer patients

OBJECTIVE

Authors have suggested that chemotherapy-induced neutropenia could represent a surrogate parameter of cancer stem cell response to treatment. Thus, the aim of this study was to evaluate the association of relative chemotherapy-induced neutropenia with survival in advanced epithelial ovarian cancer (EOC).

METHODS

A computerized database identified patients for primary advanced EOC with 6 cycles of platinum-taxane-based chemotherapy. Data collected included demographics, chemotherapy administration, laboratory evaluation, and survival outcomes. Relative neutropenia, defined as an absolute neutrophil count (ANC) <1000/mm3 at chemotherapy cycle nadir, was evaluated and correlated to PFS, OS, and platinum sensitivity (recurrence >6 months from completion of chemotherapy).

RESULTS

255 patients were identified. Patients with neutropenia (n=203) during treatment were similar to patients who never had neutropenia (n=52) in regards to age, race, body mass index (BMI), stage, histology, grade, and debulking status. Neutropenic patients demonstrated improvements in PFS (14 vs. 6 months; p=0.01), OS (45 vs. 29 months; p=0.03) and platinum sensitivity rates (69% vs. 44%; p=0.001). As the number of neutropenic episodes increased, improvements in PFS (range 6 to 17 months; p=0.07) and platinum sensitivity (range 44% to 90%; p=0.002) was demonstrated. When stratified by debulking status, neutropenia conferred a survival advantage in suboptimally debulked patients, but only demonstrated marginal improvements in optimally debulked patients.

CONCLUSIONS

Our data demonstrates that patients with chemotherapy-induced neutropenia is associated with a survival advantage in ovarian cancer, especially in suboptimally debulked patients.

Looks can be deceiving

BACKGROUND

A thorough history, physical examination, and comprehensive work-up is important to differentiate the etiology of a cervical mass in unusual cases.

CASE

A 36-year-old white female presented with heavy vaginal bleeding, pelvic pain, and an exophytic cervical mass extending to the anterior vaginal wall. She underwent cold knife cone with biopsies of the vagina. Pathology revealed dysgerminoma. Computed tomography of the abdomen and pelvis demonstrated pelvic lymphadenopathy, an enlarged uterus, and a 4 cm complex ovarian mass. The final pathology helped establish the true diagnosis.

CONCLUSION

The accurate diagnosis of rare tumors requires a broad differential diagnosis and careful review of the pathologic findings and clinical scenario.

Fertility-sparing radical abdominal trachelectomy for clear cell adenocarcinoma of the upper vagina: A case report

BACKGROUND

Clear cell adenocarcinoma (CCA) of the vagina is traditionally treated with radical surgical resection with tailored postoperative radiation when indicated. Due to a bimodal distribution, women of reproductive age are frequently affected and could benefit from radical trachelectomy to preserve fertility.

CASE

A 22 year old female was diagnosed with clinical stage I vaginal clear cell adenocarcinoma in the left fornix abutting the cervix. The patient desired future fertility; therefore, she underwent radical abdominal trachelectomy and upper vaginectomy. Twenty-eight months after initial surgery, she has no evidence of recurrence with regular menstrual cycles.

CONCLUSION

For patients with CCA of the upper vagina, where removal of the cervix is necessary, a radical trachelectomy with upper vaginectomy should be considered to conserve fertility.

Diagnostic loop electrosurgical excisional procedure for discrepancy: do preoperative factors predict presence of significant cervical intraepithelial neoplasia?

OBJECTIVE

Although pathological discrepancy between Pap smear and biopsy is an accepted indication to perform a diagnostic loop electrosurgical excision procedure (LEEP), this procedure is not without complications. Our objective was to determine the incidence of cervical intraepithelial neoplasia (CIN) 2,3 and patient factors that increase the likelihood of detecting CIN 2,3.

MATERIALS AND METHODS

We performed a retrospective chart review of patients who underwent a diagnostic LEEP for pathological discrepancy at a university-based colposcopy clinic. Pathological discrepancy is defined as a high-grade Pap smear with a colposcopically directed biopsy of CIN 1 or less. Demographic, cytological, and histological information were collected using a computerized database. The patients were divided into 2 groups (CIN 2,3 and CIN 1 or less) based on the pathology from the LEEP specimen. Patient factors were compared with final pathological results using chi(2) test, Student t test, Wilcoxon rank sum test, and multivariate analysis as indicated.

RESULTS

A total of 102 patients were identified. Seven patients had normal specimens, 3 had HPV changes, 25 had CIN 1, 29 had CIN 2, and 38 had CIN 3. Thirty-five patients (34%) had CIN 1 or less, whereas 67 patients (66%) had CIN 2,3. The 2 groups were comparable in terms of age (30.4 vs 28.1 years), parity (2.2 vs 1.9), and age of coitarche (16.3 vs 16.4 years). No statistical difference existed between the groups regarding race, smoking status, Pap smear, history of previous cytological abnormality, contraception method, number of previous sexual partners, and HIV status. The majority of patients (75%) had not undergone previous treatment of CIN. The CIN 2,3 group were more likely than the CIN 1 or less group to have had previous treatment or biopsy for CIN (66% vs 34%; p = .004). Univariate (p = .004) and multivariate (p < .001) analysis demonstrated previous treatment of CIN as the only significant factor predicting CIN 2,3.

CONCLUSION

Two thirds of women undergoing a LEEP for pathological discrepancy between Pap smear and cervical biopsy will have CIN 2,3. Women that have had previous treatment of CIN are more likely to have CIN 2,3 detected on their LEEP specimen.

The lactose repressor system: paradigms for regulation, allosteric behavior and protein folding

In 1961, Jacob and Monod proposed the operon model for gene regulation based on metabolism of lactose in Escherichia coli. This proposal was followed by an explication of allosteric behavior by Monod and colleagues. The operon model rationally depicted how genetic mechanisms can control metabolic events in response to environmental stimuli via coordinated transcription of a set of genes with related function (e.g. metabolism of lactose). The allosteric response found in the lactose repressor and many other proteins has been extended to a variety of cellular signaling pathways in all organisms. These two models have shaped our view of modern molecular biology and captivated the attention of a surprisingly broad range of scientists. More recently, the lactose repressor monomer was used as a model system for experimental and theoretical explorations of protein folding mechanisms. Thus, the lac system continues to advance our molecular understanding of genetic control and the relationship between sequence, structure and function.

Engineered disulfide linking the hinge regions within lactose repressor dimer increases operator affinity, decreases sequence selectivity, and alters allostery

The hinge domain encompasses amino acids 51-60 of lactose repressor (LacI) and plays an important role in its regulatory interaction with operator DNA. This segment makes both hinge-DNA and hinge-hinge' contacts that are critical to DNA binding. Furthermore, this small region serves as a central element in communicating the allosteric response to inducer. Introducing a disulfide bond between partner hinges within a dimer via the mutation V52C results in a protein that has increased affinity for O(1) operator DNA compared to wild-type LacI and abolishes allosteric response to inducer [Falcon, C. M., Swint-Kruse, L., and Matthews, K. S. (1997) J. Biol. Chem. 272, 26818]. We have established that this high affinity is maintained for the disulfide-linked protein even when symmetry and half-site spacing within the operator region are altered, whereas binding by the reduced protein, as for wild-type LacI, is severely diminished by these alterations. Interestingly, the allosteric response to inducer for V52C-oxidized remains intact for a small group of operator variants. Temperature studies demonstrate that the presence of the disulfide alters the thermodynamics of the protein-DNA interaction, with a DeltaC(p) of significantly smaller magnitude compared to wild-type LacI. The results presented here establish the hinge region as an important element not only for LacI high-affinity operator binding but also for the essential communication between ligand binding domains. Moreover, the results confirm that DNA sequence/conformation can profoundly influence allostery for this prototypic regulatory protein.

p53 unfolding detected by CD but not by tryptophan fluorescence

Full-length human p53 protein was examined using tryptophan fluorescence and circular dichroism spectroscopy (CD) to monitor unfolding. No significant alteration in tryptophan fluorescence for the tetrameric protein was detectable over a wide range of either urea or guanidine hydrochloride concentrations, in contrast to results with the isolated DNA binding domain [Bullock et al. (1997) Proc. Natl. Acad. Sci. USA 94, 14338]. Under similar denaturant conditions, CD demonstrated significant protein unfolding for the full-length wild-type protein, with increased apparent structure loss compared to that detected during thermal denaturation [Nichols and Matthews (2001) Biochemistry 40, 3847]. Examination of X-ray structures containing two of the four tryptophan residues of a p53 monomer suggested local environments consistent with quenched fluorophores. Exploration of p53 fluorescence using potassium iodide as a quencher confirmed that these fluorophores are already substantially quenched in the native structure, and this quenching is not relieved during protein unfolding.

Structure of a variant of lac repressor with increased thermostability and decreased affinity for operator

A single amino acid substitution, K84L, in the Escherichia coli lac repressor produces a protein that has substantially increased stability compared to wild-type. However, despite the increased stability, this altered tetrameric repressor has a tenfold reduced affinity for operator and greatly decreased rate-constants of inducer binding as well as a reduced phenotypic response to inducer in vivo. To understand the dramatic increase in stability and altered functional properties, we have determined the X-ray crystal structures of a dimeric repressor with and without the K84L substitution at resolutions of 1.7 and 3.0 A, respectively. In the wild-type dimer, K84-11, Lys84 forms electrostatic interactions at the monomer-monomer interface and is partially exposed to solvent. In the K84L-11 substituted protein there is reorientation of the N-subdomains, which allows the leucine to become deeply buried at the monomer-monomer interface. This reorientation of the N-subdomains, in turn, results in an alteration of hydrogen bonding, ion pairing, and van der Waals interactions at the monomer-monomer interface. The lysine residue at position 84 appears to exert its key effects by destabilizing the "optimal" conformation of the repressor, effectively loosening the dimer interface and allowing the repressor to adopt the conformations necessary to function as a molecular switch.

Ion concentration and temperature dependence of DNA binding: comparison of PurR and LacI repressor proteins

Purine repressor (PurR) binding to specific DNA is enhanced by complexing with purines, whereas lactose repressor (LacI) binding is diminished by interaction with inducer sugars despite 30% identity in their protein sequences and highly homologous tertiary structures. Nonetheless, in switching from low- to high-affinity DNA binding, these proteins undergo a similar structural change in which the hinge region connecting the DNA and effector binding domains folds into an alpha-helix and contacts the DNA minor groove. The differences in response to effector for these proteins should be manifest in the polyelectrolyte effect which arises from cations displaced from DNA by interaction with positively charged side chains on a protein and is quantitated by measurement of DNA binding affinity as a function of ion concentration. Consistent with structural data for these proteins, high-affinity operator DNA binding by the PurR-purine complex involved approximately 15 ion pairs, a value significantly greater than that for the corresponding state of LacI (approximately 6 ion pairs). For both proteins, however, conversion to the low-affinity state results in a decrease of approximately 2-fold in the number of cations released per dimeric DNA binding site. Heat capacity changes (DeltaC(p)) that accompany DNA binding, derived from buried apolar surface area, coupled folding, and restriction of motional freedom of polar groups in the interface, also reflect the differences between these homologous repressor proteins. DNA binding of the PurR-guanine complex is accompanied by a DeltaC(p) (-2.8 kcal mol(-1) K(-1)) more negative than that observed previously for LacI (-0.9 to -1.5 kcal mol(-1) K(-1)), suggesting that more extensive protein folding and/or enhanced structural rigidity may occur upon DNA binding for PurR compared to DNA binding for LacI. The differences between these proteins illustrate plasticity of function despite high-level sequence and structural homology and undermine efforts to predict protein behavior on the basis of such similarities.

Protein-DNA binding correlates with structural thermostability for the full-length human p53 protein

Full-length p53 protein purified from Escherichia coli in the unmodified, "latent" form was examined by several methods to correlate thermal stability of structure with functional DNA binding. Structure prediction algorithms indicate that the majority of beta-sheet structure occurs in the p53 core DNA binding domain. Circular dichroism spectra demonstrate that the intact protein is surprisingly stable with a midpoint for the irreversible unfolding transition at approximately 73 degrees C. Significant beta-sheet structural signal remains even to 100 degrees C. The persistent beta-sheet CD signal correlates with significant DNA binding (K(d) approximately nM range) to temperatures as high as 50 degrees C. These data confirm the ability of the DNA binding domain in the full-length "latent" protein to bind consensus dsDNA targets effectively in the absence of activators over a broad temperature range. In addition, we demonstrate that Ab1620 reactivity is not directly correlated with the functional activity of the full-length protein since loss of this epitope occurs at temperatures at which significant specific DNA binding can still be measured.

Operator DNA sequence variation enhances high affinity binding by hinge helix mutants of lactose repressor protein

The mechanism by which genetic regulatory proteins discern specific target DNA sequences remains a major area of inquiry. To explore in more detail the interplay between DNA and protein sequence, we have examined binding of variant lac operator DNA sequences to a series of mutant lactose repressor proteins (LacI). These proteins were altered in the C-terminus of the hinge region that links the N-terminal DNA binding and core sugar binding domains. Variant operators differed from the wild-type operator, O(1), in spacing and/or symmetry of the half-sites that contact the LacI N-terminal DNA binding domain. Binding of wild-type and mutant proteins was affected differentially by variations in operator sequence and symmetry. While the mutant series exhibits a 10(4)-fold range in binding affinity for O(1) operator, only a approximately 20-fold difference in affinity is observed for a completely symmetric operator, O(sym), used widely in studies of the LacI protein. Further, DNA sequence influenced allosteric response for these proteins. Binding of this LacI mutant series to other variant operator DNA sequences indicated the importance of symmetry-related bases, spacing, and the central base pair sequence in high affinity complex formation. Conformational flexibility in the DNA and other aspects of the structure influenced by the sequence may establish the binding environment for protein and determine both affinity and potential for allostery.

Generation of an AraC-araBAD promoter-regulated T7 expression system

An alternative and facile delivery system for T7 RNA polymerase has been devised and constructed. T7 gene 1 has been placed under control of the araBAD promoter element regulated by the AraC protein. Cotransformation of the resultant plasmid, pTara, with one containing a target gene under T7 promoter-regulated expression potentially allows repression by glucose and induction by arabinose in the range of 0.5 to 20 mM sugar concentration. To demonstrate the efficacy of this expression system, the p53 gene under T7 promoter control in two different plasmids was expressed in Escherichia coli using pTara as the source of T7 RNA polymerase. Repression and induction of p53 were achieved in both a lower and higher copy number plasmid, although the levels of induction were higher with the lower copy number expression vector. Cotransformation of an expression plasmid with pTara provides a low-cost method of T7 RNA polymerase-regulated expression that can be fine-tuned using glucose and arabinose concentrations to balance protein expression with potential solubility or toxicity problems.

Glycine insertion in the hinge region of lactose repressor protein alters DNA binding

Amino acid alterations were designed at the C terminus of the hinge segment (amino acids approximately 51-59) that links two functional domains within lactose repressor protein (LacI). Gly was introduced between Gly(58) and Lys(59) to generate Gly(58+1); Gln(60) was changed to Gly or Pro, and up to three additional glycines were inserted following Gln(60) --> Gly. All mutant proteins exhibited purification behavior, CD spectra, assembly state, and inducer binding properties similar to wild-type LacI and only small differences in trypsin proteolysis patterns. In contrast, significant differences were observed in DNA binding properties. Gly(58+1) exhibited a decrease of approximately 100-fold in affinity for O(1) operator, and sequential Gly insertion C-terminal to Gln(60) --> Gly resulted in progressively decreased affinity for O(1) operator, approaching nonspecific levels for insertion of >/=2 glycines. Where sufficient affinity for O(1) operator existed, decreased binding to O(1) in the presence of inducer indicated no disruption in the allosteric response for these proteins. Collectively, these results indicate that flexibility and/or spacing between the core and N-terminal domains did not significantly affect folding or assembly, but these alterations in the hinge domain profoundly altered affinity of the lactose repressor protein for its wild-type target sequence.

Ligand-induced conformational changes in lactose repressor: a phosphorescence and ODMR study of single-tryptophan mutants

Phosphorescence and optically detected magnetic resonance (ODMR) measurements are reported on four single-tryptophan mutants of lac repressor protein from Escherichia coli: H74W/Wless, W201Y, Y273W/Wless, and F293W/Wless, where Wless represents a protein background containing the double mutation W201Y/W220Y. The single-tryptophan residues are located in the protein core region, either in the monomer-monomer interface of the tetrameric protein or in the region of the inducer binding cleft. Inducer binding elicits large changes in the energy (0,0-band wavelength shifts) and zero-field splitting energies (ZFS) of the triplet states for each of the mutant proteins except W201Y which exhibits more modest effects. F293W/Wless exists in two distinguishable conformations, only one of which appears to be sensitive to the presence of inducer. These effects of inducer binding can be attributed to a conformational change that alters specific polar interactions that occur at each affected tryptophan site. Changes in the tryptophan triplet state indicator depend on the existence of specific polar interactions that are altered by local atomic relocations.

Thermodynamic analysis of unfolding and dissociation in lactose repressor protein

Lactose repressor protein, regulator of lac enzyme expression in Escherichia coli, maintains its structure and function at extremely low protein concentrations (<10(-)12 M). To examine the unfolding and dissociation of this tetrameric protein, structural transitions in the presence of varying concentrations of urea were monitored by fluorescence and circular dichroism spectroscopy, analytical ultracentrifugation, and functional activities. The spectroscopic data demonstrated a single cooperative transition with no evidence of folded dimeric or monomeric species of this protein. These spectroscopic transitions were reversible provided a long incubation step was employed in the refolding reaction at approximately 3 M urea. The refolded repressor protein possessed the same functional and structural properties as wild-type repressor protein. The absence of concentration dependence expected for tetramer dissociation to unfolded monomer (M4 <--> 4U) in the spectral transitions indicates that the disruption of the monomer-monomer interface and monomer unfolding are a concerted reaction (M4 <--> U4) that may occur prior to the dissociation of the dimer-dimer interface. Thus, we propose that the unfolded monomers remain associated at the C-terminus by the 4-helical coiled-coil structure that forms the dimer-dimer interface and that this intermediate is the end point detected in the spectral transitions. Efforts to confirm the existence of this species by ultracentrifugation were inhibited by the aggregation of this intermediate. Based upon these observations, the wild-type fluorescence and CD data were fit to a model, M4 <--> U4, which resulted in an overall DeltaG degrees for unfolding of 40 kcal/mol. Using a mutant protein, K84L, in which the monomer-monomer interface is stabilized, sedimentation equilibrium results demonstrated that the dimer-dimer interface of lac repressor could persist at higher levels of urea than the monomer-monomer interface. The tetramer-dimer transition monitored using this mutant repressor yields a DeltaG degrees of 20.4 kcal/mol. Using this free energy value for the dissociation process of U4 <--> 4U, an overall free energy change of approximately 60 kcal/mol was calculated for dissociation of all interfaces and unfolding of the tetrameric lac repressor, reflecting the exceptional stability of this protein.

Substitutions at histidine 74 and aspartate 278 alter ligand binding and allostery in lactose repressor protein

In the inducer-bound structure of the lac repressor protein, the side chains of H74 and D278 are positioned to form an ion pair between monomers that appears to be disrupted upon operator binding (Lewis, M., Chang, G., Horton, N. C., Kercher, M. A., Pace, H. C., Schumacher, M. A., Brennan, R. G., and Lu, P. (1996) Science 271, 1247-1254). A series of single substitutions at H74 and D278 and a double mutant, H74D-D278H, were generated to determine the influence of this interaction on ligand binding and allostery in lac repressor. Introduction of apolar amino acids at H74 resulted in distinct effects on ligand binding. Alanine and leucine substitutions decreased operator binding, while tryptophan and phenylalanine increased affinity for operator DNA. Introduction of a negatively charged residue at position 74 in H74D had minimal effects, and "inverting" the side chains in H74D/D278H did not significantly alter inducer or operator binding at neutral pH. In contrast, all substitutions of D278 increased affinity for operator DNA and diminished inducer binding. These observations can be interpreted in the context of the Monod-Wyman-Changeux model. If a salt bridge were essential for stabilizing or destabilizing the inducer-bound conformation, a mutation at either residue that interrupts this interaction should have a similar effect on allostery. Because the type and degree of alteration in ligand binding properties depended on the nature of the substitution at these residues, the individual roles played by H74 and D278 in lac repressor allostery appear more important than their direct contact across the monomer-monomer interface.

Kinetic and thermodynamic studies of purine repressor binding to corepressor and operator DNA

The kinetic and thermodynamic parameters for purine repressor (PurR)-operator and PurR-guanine binding were determined using fluorescence spectroscopy and nitrocellulose filter binding. Operator binding affinity was increased by the presence of guanine as demonstrated previously (Choi, K. Y., Lu, F., and Zalkin, H. (1994) J. Biol. Chem. 269, 24066-24072; Rolfes, R. J., and Zalkin, H. (1990) J. Bacteriol. 172, 5637-5642), and conversely guanine binding affinity was increased by the presence of operator. Guanine enhanced operator affinity by increasing the association rate constant and decreasing the dissociation rate constant for binding. Operator had minimal effect on the association rate constant for guanine binding; however, this DNA decreased the dissociation rate constant for corepressor by approximately 10-fold. Despite significant sequence and structural similarity between PurR and LacI proteins, PurR binds to its corepressor ligand with a lower association rate constant than LacI binds to its inducer ligand. However, the rate constant for PurR-guanine binding to operator is approximately 3-fold higher than for LacI binding to its cognate operator under the same solution conditions. The distinct metabolic roles of the enzymes under regulation by these two repressor proteins provide a rationale for the observed functional differences.

Comparison of simulated and experimentally determined dynamics for a variant of the Lacl DNA-binding domain, Nlac-P

Recent advances in the experimentally determined structures and dynamics of the domains within LacI provide a rare context for evaluating dynamics calculations. A 1500-ps trajectory was simulated for a variant of the LacI DNA-binding domain, which consists of the first three helices in LacI and the hinge helix of the homologous PurR. Order parameters derived from dynamics simulations are compared to those obtained for the LacI DNA-binding domain with 15N relaxation NMR spectroscopy (Slijper et al., 1997. Biochemistry. 36:249-254). The MD simulations suggest that the unstructured loop between helices II and III does not exist in a discrete state under the conditions of no salt and neutral pH, but occupies a continuum of states between the DNA-bound and free structures. Simulations also indicate that the unstructured region between helix III and the hinge helix is very mobile, rendering motions of the hinge helix essentially independent of the rest of the protein. Finally, the alpha-helical hydrogen bonds in the hinge helix are broken after 1250 ps, perhaps as a prelude to helix unfolding.

Ligand-induced conformational changes in lactose repressor: a fluorescence study of single tryptophan mutants

A key element in the ability of lac repressor protein to control transcription reversibly is the capacity to assume different conformations in response to ligand binding. To investigate regions of the protein involved in these conformational changes, mutant repressor proteins containing single tryptophans were created by mutating each of the two native tryptophan residues to tyrosine and changing the residue of interest to tryptophan. Tryptophans substituted in the following locations were highly accessible to quenchers with no changes in fluorescence or quenching properties in the presence of ligands: in the N-terminal helix-turn-helix for Y7, at the junction between the N-terminus and N-subdomain for L62, in the N-subdomain of the monomer-monomer interface for residue E100 or Q117, or at the C-terminal region for K325. Tryptophan at position F226 in the C-subdomain subunit interface was only moderately exposed to quenchers and unresponsive to ligands. In contrast, the fluorescence and quenching properties of single tryptophans placed in the central region of the protein were affected by ligands. Inducer binding altered the accessibility to quencher for tryptophan at H74 or F293, but no changes were detected upon binding operator. Exposure of tryptophan at the position occupied by Y273 was affected by both inducer and operator, indicating alterations in this region by both ligands. These results suggest that, in the areas of the lac repressor probed by these substitutions, the inducer-bound form differs from the conformation of the unliganded form.

Designed disulfide between N-terminal domains of lactose repressor disrupts allosteric linkage

Substitution of Cys for Val at position 52 of the lac repressor was designed to permit disulfide bond formation between the two N-terminal DNA binding domains that comprise an operator DNA binding site. This position marks the closest approach of these domains based on the x-ray crystallographic structures of the homologous purine holorepressor-operator complex and lac repressor-operator complex (Schumacher, M. A., Choi, K. Y., Zalkin, H., and Brennan, R. G. (1994) Science 266, 763-770; Lewis, M., Chang, G., Horton, N.C., Kercher, M. A., Pace, H. C., Schumacher, M. A., Brennan, R. G., and Lu, P. (1996) Science 271, 1247-1254). The V52C mutation was generated by site-specific methods, and the mutant protein was purified and characterized. In the reduced form, V52C bound operator DNA with slightly increased affinity. Exposure to oxidizing conditions resulted in disulfide bond formation, and the oxidized protein bound operator DNA with approximately 6-fold higher affinity than wild-type protein. Inducer binding for both oxidized and reduced forms of V52C was comparable to wild-type lac repressor. In the presence of inducer, the reduced protein exhibited wild-type, diminished DNA binding. In contrast, DNA binding for the oxidized form was unaffected by inducer, even at 1 mM. Thus, the formation of the designed disulfide between Cys52 side chains within each dimer renders the protein-operator complex unresponsive to sugar binding, presumably by disrupting the allosteric linkage between operator and inducer binding.

Lactose repressor protein: functional properties and structure

The lactose repressor protein (LacI), the prototype for genetic regulatory proteins, controls expression of lactose metabolic genes by binding to its cognate operator sequences in E. coli DNA. Inducer binding elicits a conformational change that diminishes affinity for operator sequences with no effect on nonspecific binding. The release of operator is followed by synthesis of mRNA encoding the enzymes for lactose utilization. Genetic, chemical and physical studies provided detailed insight into the function of this protein prior to the recent completion of X-ray crystallographic structures. The structural information can now be correlated with the phenotypic data for numerous mutants. These structures also provide the opportunity for physical and chemical studies on mutants designed to examine various aspects of lac repressor structure and function. In addition to providing insight into protein structure-function correlations, LacI has been utilized in a wide variety of applications both in prokaryotic gene expression and in eukaryotic gene regulation and studies of mutagenesis.

Combinatorial mutations of lac repressor. Stability of monomer-monomer interface is increased by apolar substitution at position 84

To examine the monomer-monomer subunit interface in the lac repressor, a mutation that generates dimeric protein (deletion of C-terminal amino acids to disrupt the dimer-dimer interface) has been combined with amino acid substitutions that alter the monomer-monomer interface (substitution at Lys84 or Tyr282). Dimeric proteins with significantly increased stability to urea denaturation were formed by the introduction of the apolar amino acids Ala or Leu in lieu of Lys84 in concert with the deletion of 11 C-terminal amino acids. K84A/-11 deletion protein retained wild-type affinity for operator DNA, while K84L/-11 deletion protein displayed operator affinity similar to its parent tetramer. To assess further the influence of monomer-monomer interface stability on assembly and DNA binding, triple mutants were generated with Y282D, an alteration that disrupts assembly completely in the wild-type background. The triple mutants were dimeric, but they exhibited diminished dimer stability to urea denaturation and decreased operator affinity compared with the double mutations. These results demonstrate directly the stabilizing influence of apolar substitution at position 84 on the monomer-monomer interface.

Differences in water release with DNA binding by ultrabithorax and deformed homeodomains

The amino acid sequences of the homeodomains (HD) within the Ultrabithorax (Ubx) and Deformed (Dfd) proteins from Drosophila melanogaster are highly conserved despite distinct genetic regulatory functions for these proteins in embryonic development. We reported recently that Ubx-HD binding to a single target site displayed significantly increased affinity and greater salt concentration dependence at lower pH; in contrast, Dfd-HD did not show pH dependence in its DNA binding properties [Li, L., et al. (1996) Biochemistry 35, 9832-9839]. We demonstrate in this study that water activity differentially affects Ubx-HD and Dfd-HD DNA binding affinity. The sensitivity of the protein-DNA binding constant to osmotic pressures generated by neutral solutes was measured, and the formation of the Ubx-HD-DNA complex is associated with significantly greater water release than that of the Dfd-HD-DNA complex. No influence of pH on water release was detected for either HD. Experiments with chimeric Ubx-Dfd homeodomains demonstrated that the C-terminal region of the Ubx-HD is the primary determinant for the greater water release associated with DNA binding for this protein. DNA sequences do not exert a significant effect on the magnitude of water release associated with protein-DNA binding for Ubx-HD and the chimeric HD, UDU.

pH-dependent enhancement of DNA binding by the ultrabithorax homeodomain

Ultrabithorax (Ubx) and Deformed (Dfd) proteins of Drosophila melanogaster contain homeodomains (HD) that are structurally similar and recognize similar DNA sequences, despite functionally distinct genetic regulatory roles for Ubx and Dfd. We report in the present study that Ubx-HD binding to a single optimal target site displayed significantly increased affinity and higher salt concentration dependence at lower pH, while Dfd-HD binding to DNA was unaffected by pH. Results from studies of chimeric Ubx-Dfd homeodomains showed that the N- and C-terminal regions of the Ubx-HD are required for this pH dependence. The increase in binding affinity at lower pH was greater for the Ubx optimal binding site than for other DNA binding sites, indicating that subtle sequence alterations in DNA binding sites may influence pH-dependent behavior. These data demonstrate enhanced DNA binding affinity at lower pH for the Ubx-HD in vitro and suggest the potential for significant discrimination of DNA binding sites in vivo.

Protective effect of vitamin E on lymphocyte growth capacity during incubation in vitro

Vitamin E, an essential lipid-soluble micronutrient, plays an important role in the immune system and serves as an immunostimulant in geriatric subjects. Using an in vitro incubation to simulate aging processes, we find that vitamin E mitigates loss of growth capacity in lymphocytes. Vitamin E presence during in vitro incubation did not affect significantly the level of peroxidation, the effects of exogenous IL-2, PGE2, or indomethacin, nor levels of IL-2 production. Thus, the preservative effect on lymphocyte growth by vitamin E is not due primarily to its antioxidant function or to interleukin-2 or prostaglandin effects. The decreased growth capacity generated by in vitro incubation is accompanied by a variety of cellular alterations, including decreased CD5 surface antigen, enhanced suppression by adherent cells, and impaired communication between lymphocytes and adherent cells. The decrease in CD5 surface antigen correlates inversely with the cell density required for maximal cell proliferation, and the diminished CD5 levels were unaltered by vitamin E presence during the aging process. In contrast, protection of T-cell proliferative capacity by vitamin E in vitro correlates with diminished suppression by adherent cells and normalized interaction between lymphocytes and adherent cells.

Human lymphocytes incubated in vitro share multiple characteristics with geriatric-derived lymphocytes: a potential in vitro model for aging?

Aging involves a complicated set of parallel reactions that result in multiple cellular and organismic changes and may eventuate in chronic illness. In the immune system, several alterations that correlate with age have been established. In the present study, we report the results of incubating lymphocytes in vitro in whole blood and, employing measures known to be age-dependent, compare these cells 'aged' in vitro with cells from geriatric patients aged in vivo. Cells from blood aged in vivo and incubated in vitro share a number of common characteristics that include decreased growth capacity, shifted growth patterns, increased suppression by adherent cells, decrease in CD5 surface antigen, similar responses to addition of exogenous IL-1, IL-2, PGE2, or indomethacin, and similar production of PGE2. Differences found between in vivo aging and in vitro incubation are IL-2 plasma levels and IL-2 production by activated cells monitored in conditioned minimal medium. Based on these observations, this in vitro system provides a simple method to generate cells that exhibit a very significant subset, but not all, of the characteristics associated with in vivo aging in lymphocytes.

Role of Asp274 in lac repressor: diminished sugar binding and altered conformational effects in mutants

The role of Asp274 in inducer binding of lac repressor has been explored by spectroscopic measurements, fluorescence quenching, in vitro induction assays, and chemical modification of mutants with conservative substitutions at this site. Although no fluorescence emission shift or characteristic UV difference spectrum was observed at high inducer concentration, fluorescence quenching, effects on operator binding, and chemical modification results indicate indirectly that the mutants Asp274-->Asn and Asp274-->Glu bind sugar, albeit with very low affinity (> 0.1 M). Consistent with very weak inducer binding indicated by protection from fluorescence quenching by iodide, operator binding activity of these two mutant proteins is altered at very high IPTG concentration, although in opposite directions. The distinct effects of inducer on operator binding in these two mutant proteins as well as substantial differences in the effect of sugar ligand on chemical modification of Cys107 and Cys140 by 2-(bromoacetamido)-4-nitrophenol suggest that the conformation of the protein before and after association with sugar may differ in these mutant proteins. Fluorescence quenching assays of lac mutant proteins at Asp274 indicate the proximity of Trp220 to the side chain at position 274, consistent with the location of this residue in the structural model of lac repressor and in the crystallographic structure of the homologous purine repressor. From these results, we conclude that Asp274 is in the inducer binding site, that the character of this residue is crucial to inducer binding, and that interaction of sugar with the side chain at this position may be associated with the conformational change necessary for generating high affinity ligand binding.

Characterization of mutants affecting the KRK sequence in the carboxyl-terminal domain of lac repressor

The lac repressor carboxyl-terminal region is required for tetramer assembly and protein stability. To further investigate this region, especially the unusual sequence KRK, four deletion mutants eliminating the carboxyl-terminal 34, 35, 36, and 39 amino acids and five substitution mutants at the position of Arg-326, R326K, R326A, R326E, R326L, and R326W, were constructed using site-specific mutagenesis. The -34-amino-acid (aa) mutant, missing the most carboxyl-proximal lysine from the KRK sequence, exhibited lower affinity for both operator and inducer and lower protein stability than dimeric proteins studied previously. The -35-aa mutant with RK missing, as well as -36 aa and -39 aa, for which the entire KRK sequence was deleted, yielded inactive polypeptides that could be detected only by monoclonal antibody for lac repressor. In the Arg-326 mutant proteins, operator binding affinity was decreased by approximately 6-fold, the shift in inducer binding at elevated pH was diminished, and protein stability was decreased. Dramatic decreases in protein expression and stability occurred with substitution at position 326 by glutamate, leucine, or tryptophan. These results suggest that Arg-326 plays an important role in the formation of the proper tertiary structure necessary for inducer and operator affinity and for protein stability.

Glucose and insulin responses in isolated human lymphocytes reflect in vivo status: effects of VLCD treatment

Human lymphocyte growth response to mitogen was examined in vitro under different conditions to monitor aspects of carbohydrate utilization in three groups: obese nondiabetic, obese/NIDDM, and normal-weight individuals. Although lymphocyte growth capacity in minimal medium for these three groups was found to be similar at a glucose concentration of 72 micrograms/ml in the absence of insulin or glycerol, differences in mitogen-stimulated growth were observed at lower glucose concentrations or in the presence of insulin or glycerol. Interestingly, these metabolic alterations in lymphocytes can be normalized by treating obese and obese/NIDDM subjects with a very low calorie diet (VLCD) regimen. The results of this study indicate that lymphocyte culture in a defined medium may provide a mechanism to examine different metabolic states and to evaluate treatment regimens (diet, exercise, etc.) for obese and NIDDM subjects.

Subunit dissociation affects DNA binding in a dimeric lac repressor produced by C-terminal deletion

The reduction in apparent operator binding affinity found for dimeric lac repressor proteins produced by disruption of the C-terminal coiled-coil interaction has been proposed to derive from thermodynamic linkage between dimer-monomer and protein-DNA equilibria [Brenowitz et al. (1991) J. Biol. Chem. 266, 1281]. To explore this linkage, we have employed two dimeric proteins, a deletion mutant (-11 aa) missing 11 amino acids at the C-terminus that has diminished apparent operator binding affinity [Chen & Matthews (1992) J. Biol. Chem. 267, 13843] and a mutant (R3) that binds to operator with wild-type affinity in which the C-terminal leucine heptad repeats of lac repressor were replaced by the GCN4 dimerization sequence [Alberti et al. (1993) EMBO J. 12, 3227; Chen et al. (1994) J. Biol. Chem. (in press)]. To avoid the complexities of working at the low concentrations of protein required by the high affinity between the monomer subunits, urea denaturation studies were undertaken to determine the free energy change(s) for dissociation and/or unfolding. Under denaturing conditions, dimer dissociation and monomer unfolding were found to be concerted processes, and the free energy change for the overall process of dimer to unfolded monomer was derived from these experiments for the two dimeric proteins. A monomeric mutant (Y282D) of the lactose repressor was examined to determine the free energy change of protomer unfolding. From the combination of these data, the Kd for -11 aa dimer dissociation was determined to be 7.7 x 10(-8) M, and the corresponding value for R3 protein was 3.2 x 10(-11) M.(ABSTRACT TRUNCATED AT 250 WORDS)

Wild-type operator binding and altered cooperativity for inducer binding of lac repressor dimer mutant R3

Substitution of the C-terminal leucine heptad repeat region of the normally tetrameric lactose repressor by the leucine heptad repeat dimerization domain of GCN4 protein resulted in cell extracts containing protein, designated R3, which behaved as a dimer based on gel retardation analysis of DNA binding (Alberti, S., Oehler, S., von Wilcken-Bergmann, B., and Müller-Hill, B. (1993) EMBO J. 12, 3227-3236). We have purified this R3 protein and characterized its properties in comparison with the wild-type repressor. R3 protein elutes from a molecular sieve with a Stokes radius characteristic of a dimer and a deduced molecular mass of 66 kDa. Unlike other dimeric repressors, produced by deletion or mutation in the leucine heptad repeat region, which display reduced apparent operator affinity, R3 binds to operator DNA sequences with wild-type equilibrium and kinetic properties. Although inducer affinity at neutral pH is similar for R3 and wild-type protein, at elevated pH the R3 protein undergoes a slightly smaller decrease in affinity and exhibits minimal cooperativity in sugar binding compared with the wild-type protein. Interestingly, in the presence of operator DNA, a state in which inducer binding to wild-type repressor is also of reduced affinity and slightly cooperative, R3 binding affinity is decreased to a greater extent, and the protein displays higher cooperativity than wild-type repressor. Consistent with inducer binding data in the presence of operator, the release of operator from R3 protein requires a higher sugar concentration than wild-type protein. These results are interpreted in the context of alterations involving the subunit interface which affect the allosteric behavior of the repressor protein.

Identification and characterization of aspartate residues that play key roles in the allosteric regulation of a transcription factor: aspartate 274 is essential for inducer binding in lac repressor

To explore the roles of three aspartate residues, Asp88, Asp130, and Asp274, found in the proposed inducer binding site of lac repressor [Sams, C. F., Vyas, N. K., Quiocho, F. A., & Matthews, K. S. (1984) Nature 310, 429-430], each site was substituted with alanine, glutamate, lysine, or asparagine by site-specific mutagenesis. The mutations at the Asp88 site resulted in a 5-13-fold decrease in inducer binding affinity, largely due to an increase in the inducer dissociation rate constants for these mutants. In addition, the mutant proteins Asp88-->Ala and Asp88-->Lys exhibited altered allosteric behavior for inducer binding. These data conflict with the original hypothesis placing Asp88 in the inducer binding site, but are in agreement with a recent model that places this amino acid close to the subunit interface involved in cooperativity associated with inducer binding [Nichols, J. C., Vyas, N. K., Quiocho, F. A., & Matthews, K. S. (1993) J. Biol. Chem. 268, 17602-17612; Chen, J., & Matthews, K. S. (1992) J. Biol. Chem. 267, 13843-13850]. Substitution at Asp130 did not alter the inducer binding affinity nor other binding activities. Thus, this amino acid is not crucial in the binding to beta-substituted monosaccharides or in protein function. In stark contrast, all mutant proteins with substitutions at the Asp274 site exhibited no detectable inducer binding. With the exception of Asp274-->Lys, the structures of these mutant proteins appear to be similar to wild-type. The data demonstrate that Asp274 plays a crucial role in inducer binding of this transcriptional regulator.

Construction of a dimeric repressor: dissection of subunit interfaces in Lac repressor

Formation of the lactose repressor tetramer is postulated to involve two subunit interfaces, one primarily contributing to monomer-monomer assembly to dimer and the second to dimer-dimer association to tetramer. The latter interface requires a heptad repeat of three leucines at the C-terminus of lac repressor that is presumed to form an abbreviated coiled-coil motif [Chakerian, A. E., Tesmer, V. M., Manly, S. P., Brackett, J. K., Lynch, M. J., Hoh, J. T., & Matthews, K. S. (1991) J. Biol. Chem. 266, 1371-1374; Alberti, S., Oehler, S., von Wilcken-Bergmann, B., Krämer, H., & Müller-Hill, B. (1991) New Biol. 3, 57-62; Chen, J., & Matthews, K. S. (1992) J. Biol. Chem. 267, 13843-13850]. To strengthen the dimer-dimer interface, this motif was extended by the addition of one and two leucine heptad repeat units to the C-terminus by site-specific insertion mutagenesis. The tetrameric products displayed operator and inducer affinity essentially indistinguishable from the wild-type repressor. In order to probe the effect of the elongated coiled-coil on assembly of the repressor tetramer, the other of the two postulated subunit interfaces was disrupted by introducing a point mutation (Y282D) that yields a monomeric protein in the wild-type background. Both elongated mutant repressors were able to assemble into dimeric species, apparently due to the strengthened subunit association at the C-terminal region compared to the wild-type repressor. These results further confirm the role of a coiled-coil structure in the formation of tetramer in the lac repressor.(ABSTRACT TRUNCATED AT 250 WORDS)

Dietary deprivation of B-vitamins reflected in murine splenocyte proliferation in vitro

The effect of murine dietary deprivation of specific B-vitamins on in vitro splenocyte proliferative response in short-term tissue culture was examined in serum-free, protein-free, minimal medium. Using different media formulations, incorporation of [3H]thymidine was used to monitor the relative growth capacity of phytohemagglutinin-stimulated splenocytes from mice exposed to different diets. The results demonstrate that the growth deficit observed in vitro in the absence of specific vitamin(s) in the medium correlates only to those specific vitamin(s) eliminated from the diet. Dietary repletion is followed by restoration of a normalized response in vitro. The finding that murine dietary experience is reflected in vitro in splenocyte proliferative response monitored by [3H]thymidine incorporation suggests that human dietary experience might be monitored by similar analysis of human peripheral blood lymphocyte response.

trp repressor mutations alter DNA complex stoichiometry

We have examined the interaction of a series of mutant trp repressors with various operator DNA sequences using gel retardation. Binding to 40 base pairs (bp) TrpEDCBA operator yielded patterns distinct from the wild-type protein for superrepressors EK13, EK18, and EK49, with a protein-DNA complex of higher stoichiometry (three dimers/operator) than observed for wild-type repressor (two dimers/operator). This higher stoichiometry complex may contribute to the enhanced binding affinity and higher protein-operator stability observed for the superrepressors. In contrast, DN46 displayed the same complexes characteristic of the wild-type protein, although the complex of a single dimer with operator was more prominent in the DN46 binding pattern than wild-type despite higher apparent affinity of this protein for TrpEDCBA operator than wild-type protein. The binding of AV77 was indistinguishable from the wild-type protein. Similar patterns to that found for TrpEDCBA were also observed for the 40-bp aroH operator and symmetrized derivatives of TrpEDCBA for these superrepressors. Binding of EK13, EK18, and EK49 superrepressors to half-site DNAs, composed of 20 bp of TrpEDCBA sequence coupled with 20 bp of lac operator sequence, yielded 2:1 complex as the primary product with no detectable 3:1 complex; thus, two half-sites appear to be required for generation of the 3:1 complex. Mutation in the tryptophan-binding site can also generate higher order complexes with TrpEDCBA DNA as demonstrated by the binding of VA58; the presence of 3:1 complex with this protein was also dependent on the presence of two half-sites. In addition to effects of sequence changes in the protein, the ligand employed can influence the binding pattern, as demonstrated for EK49 and VA58 using 5-methyl-tryptophan; the 3:1 complex is produced more prominently and at lower protein concentration for both mutants. It is apparent from these data that binding of the trp repressor to DNA is influenced by the operator sequence, the nature of the corepressor, as well as interactions (perhaps involving the N-terminal regions) that occur within and between the dimeric structure of this protein.

Characterization of the two tryptophan residues of the lactose repressor from Escherichia coli by phosphorescence and optical detection of magnetic resonance

The native lactose repressor from Escherichia coli (Lac Rep) and two single-point mutants, W220Y and W201Y, were investigated using low-temperature phosphorescence and optical detection of magnetic resonance (ODMR) spectroscopy. Emission from two tryptophan residues was evident in the phosphorescence spectrum of native Lac Rep at 77 K. Using the single-point mutants, the triplet-state properties of tryptophans 201 and 220 were obtained independently. Trp 220 was characterized as a partially solvent-exposed residue (0,0 band centered at 409.5 nm), while tryptophan 201 exhibited the properties of a buried residue (0,0 band centered at 413.5 nm). Both single-point mutant proteins experienced changes in tryptophan triplet-state properties as a result of binding either of two inducer sugars: isopropyl beta-D-thiogalactoside, a monosaccharide, or melibiose, a disaccharide. Putative singlet-singlet energy transfer from tryptophan 220 to tryptophan 201 was also investigated, but the quantitative results must be viewed with some caution.

Dependence of trp repressor-operator affinity, stoichiometry, and apparent cooperativity on DNA sequence and size

A series of chemically synthesized trp and mutant operator DNAs was employed to examine trp repressor binding. Although only a single repressor-operator complex was observed for most DNAs as reported previously, varying DNA sequence revealed two retarded complexes with an additional band of faster mobility. The relative intensity of the two retarded bands with varying repressor concentrations suggests that cooperative interactions between dimers may occur in the formation of the predominant repressor-operator complex. Direct stoichiometry measurements demonstrated that a 2:1 stoichiometry (two dimers per operator) is found in the primary repressor-operator complex band and that a 1:1 stoichiometry is observed, when present, for the minor repressor-operator complex band of faster mobility. Similar retardation patterns with a single complex of 2:1 stoichiometry were observed for 40-base pair (bp) trp operators corresponding to TrpEDCBA, aroH, and Trp-PL (a derivative of TrpEDCBA with increased symmetry) operator sequences as well as to hybrid operators containing a half-binding site from TrpEDCBA in conjunction with lac operator sequences, although the apparent affinity for the half-site DNAs was diminished by 10-fold. In contrast, the prominence of the 1:1 dimer-operator complex for Trp-PR, a different derivative of TrpEDCBA with increased symmetry, suggests that sequence context may diminish cooperativity between dimers. The stoichiometry observed was also dependent on the length of TrpEDCBA operator DNA used, shifting from primarily 2:1 for 40- and 33-bp TrpEDCBA DNA to primarily 1:1 for 29-, 26-, and 20-bp TrpEDCBA DNAs. In addition, the stability of the repressor-operator complex to electrophoresis is reduced for DNA lengths of 33, 29, and 26 bp. Based on the binding data and footprinting patterns for two hybrid 40-bp TrpEDCBA/lac half-binding site DNAs, it appears that repressor associates tightly to the specific trp half-site, whereas the nonspecific half of the DNA is more loosely bound. These results suggest that repressor dimer-dimer interaction may be an important feature in the trp repressor-operator interaction.

Trp repressor interaction with bromodeoxyuridine-substituted operators alters UV-induced perturbation pattern in a sequence-dependent manner

In order to explore DNA sites influenced by the trp repressor-operator interaction, bromodeoxyuridine (BrdU) was chemically incorporated into the TrpEDCBA, TrpR, and aroH operators at selected thymidine positions. Different patterns of repressor protection from strand scission in the two halves of complexes with the TrpEDCBA, TrpR, and aroH operators suggest different local environments despite the highly symmetric sequences. Although protection was observed at multiple sites in the operators in the presence of repressor, UV irradiation did not lead to a cross-linked repressor-operator complex. This result indicates the absence of close contacts in the major groove between suitable repressor residues and the 5-methyl of thymidines. Upon trp repressor binding and UV irradiation, in addition to protection from strand scission, multiplets were observed at some sites, notably within CTAG sequences in the BrdU-substituted operators. This phenomenon (termed band migration) may result from distortion by the trp repressor of the BrdU-substituted operator DNA and consequent exposure of different sites along the backbone to strand scission. Interestingly, UV footprinting of two BrdU-substituted TrpEDCBA variant operators showed different patterns when base pair symmetry was matched to each side of the symmetry axis. These observations suggest that alterations in the UV photolysis pattern in response to protein binding result from DNA structural alterations that are sequence dependent.

Model of lactose repressor core based on alignment with sugar-binding proteins is concordant with genetic and chemical data

Using primary sequence similarity to arabinose-binding protein, D-glucose/D-galactose-binding protein, and ribose-binding protein (Vyas, N. K., Vyas, M. N., and Quiocho, F. A. (1991) J. Biol. Chem. 266, 5226-5237; Mowbray, S. L., and Cole, L. B. (1992) J. Mol. Biol. 225, 155-175), the core domain (residues 62-323) of the bacterial regulatory protein lac repressor has been aligned to these sugar-binding proteins of known structure. Although the sequence identity is not striking, there is strong overall homology based on two separate matrix scoring systems (minimum base change per codon (MBC/C) and amino acid homology per residue (AAH/R)) (mean score: MBC/C < 1.25, AAH/R > 5.50; random sequences: MBC/C = 1.45, AAH/R = 4.46). Similarly, the predicted secondary structure of the repressor exhibits excellent agreement with the known secondary structures of the sugar-binding proteins. Using this primary sequence alignment, the tertiary structure of the core domain of the lac repressor has been modeled based on the known structures of the sugar-binding proteins as templates. While the structure deduced for the repressor is hypothetical, the model generated allows a comparison between the predicted tertiary arrangement and the wealth of genetic and chemical data elucidated for the repressor. Important residues involved in operator and sugar binding and in protein assembly have been identified using genetic methods, and placement of these residues in the model is consistent with their known function. This approach, therefore, provides a means to visualize the core domain of the lac repressor that allows interpretation of genetic and chemical data for specific residues and rational design of future experiments.

Lysine 84 is at the subunit interface of lac repressor protein

Mutations have been generated at the Lys84 site of the lac repressor to explore its predicted role in inducer binding and/or subunit interaction. Four single mutations, Lys84-->Ala, Lys84-->Leu, Lys84-->Arg, and Lys84-->Glu, have been generated by site-specific mutagenesis. In addition, the mutation Tyr282-->Asp, which results in a monomeric repressor, has been coupled with these four single mutants to generate the four corresponding double mutants. Unchanged inducer binding affinities in all Lys84 mutants except Lys84-->Arg suggest that Lys84 does not contribute energy to inducer binding and is not found in the inducer-binding site as previously proposed (Sams, C. F., Vyas, N. K., Quiocho, F. A., and Matthews, K. S. (1984) Nature 310, 429-430). Interestingly, the double mutants with hydrophobic side chains at the Lys84 site are tetramers, while those with charged side chains remain monomers. This result agrees with the recent model of the lac repressor (Nichols, J. C., Vyas, N. K., Quiocho, F. A., and Matthews, K. S. (1993) J. Biol. Chem. 268, 17602-17612), in which Lys84 is mapped by sequence alignment to the same face of the subunit as Tyr282. More detailed inducer binding, operator binding, and immunoblotting studies show that all the mutations at Lys84 have quaternary structures that deviate from wild-type protein, providing supportive evidence for the model placing this residue on the surface of the monomer subunit. Substitution of Lys84 by Ala or Leu results in 100-200-fold decreased association and dissociation rate constants for inducer binding and biphasic character. This decrease can be rescued at least partially in the respective double mutants at elevated pH, at which wild-type repressor shows a 10-fold decrease in affinity and cooperativity in inducer binding. In all substitutions with Ala or Leu, immunoblotting patterns with monoclonal antibody, an assay sensitive to alterations in quaternary structure, are distinct from wild-type repressor. Although substitution with Arg at position 84 yields a protein with 10-fold lower inducer binding affinity, the mutant shows decreased pH dependence of inducer binding. Substitution at this site with Glu results in cooperativity at neutral pH with no change in inducer binding at elevated pH. In addition, operator binding affinity of this mutant is affected by elevated pH, a phenomenon not observed in wild-type repressor. These changes in inducer and operator binding properties appear to be related to the altered quaternary structure of these mutants at Lys84.

Deletion of lactose repressor carboxyl-terminal domain affects tetramer formation

The carboxyl-terminal sequence of the lac repressor protein contains heptad repeats of leucines at positions 342, 349, and 356 that are required for tetramer assembly, as substitution of these leucine residues yields solely dimeric species (Chakerian, A. E., Tesmer, V. M., Manly, S. P., Brackett, J. K., Lynch, M. J., Hoh, J. T., and Matthews, K. S. (1991) J. Biol. Chem. 266, 1371-1374; Alberti, S., Oehler, S., von Wilcken-Bergmann, B., Krämer, H., and Müller-Hill, B. (1991) New Biol. 3, 57-62). To further investigate this region, which may form a leucine zipper motif, a family of lac repressor carboxyl-terminal deletion mutants eliminating the last 4, 5, 11, 18, and 32 amino acids (aa) has been constructed. The -4 aa mutant, in which all of the leucines in the presumed leucine zipper are intact, is tetrameric and displays operator and inducer binding properties similar to wild-type repressor. The -5 aa, -11 aa, -18 aa, and -32 aa deletion mutants, depleted of 1, 2, or all 3 of the leucines in the heptad repeats, are all dimeric, as demonstrated by gel filtration chromatography. Circular dichroism spectra and protease digestion studies indicate similar secondary/tertiary structures for the mutant and wild-type proteins. Differences in reaction with a monoclonal antibody specific for a subunit interface are observed for the dimeric versus tetrameric proteins, indicative of exposure of the target epitope as a consequence of deletion. Inducer binding properties of the deletion mutants are similar to wild-type tetrameric repressor at neutral pH. Only small differences in affinity and cooperativity from wild-type are evident at elevated pH; thus, the cooperative unit within the tetramer appears to be the dimer. "Apparent" operator binding affinity for the dimeric proteins is diminished, although minimal change in operator dissociation rate constants was observed. The diminution in apparent operator affinity may therefore derive from either 1) dissociation of the dimeric mutants to monomer generating a linked equilibrium or 2) alterations in intrinsic operator affinity of the dimers; the former explanation is favored. This detailed characterization of the purified mutant proteins confirms that the carboxyl-terminal region is involved in the dimer-dimer interface and demonstrates that cooperativity for inducer binding is contained within the dimer unit of the tetramer structure.