Wild-type p53 induction mediated by replication-deficient adenoviral vectors.

Replication-deficient E1-/E3-deleted adenoviral vectors are commonly used to introduce transgenes into cells in vitro and have been used for certain kinds of gene therapy protocols in vivo. We have demonstrated that transduction of cells using these vectors can induce p53 expression in cells containing a wild-type p53 gene. This response is different from p53 induction observed after DNA damage because the time course of induction is slower and because it occurs in cells with an attenuated DNA damage response. However, this vector-induced p53 is transcriptionally active and, therefore, p53 function is not inactivated by viral proteins. The mechanism of induction appears to be an increased rate of protein translation because immunoprecipitation analyses demonstrated increased levels of 35S-labeled p53 protein, even after a short 15-min labeling time. Induction of p53 by adenoviral vectors may have various effects on transduced cells, including apoptosis and altered chemotherapy chemosensitivity. Therefore, the influence of the vector might confound the impact of any particular gene used in a gene therapy application.

IL-2 adenovector-transduced autologous tumor cells induce antitumor immune responses in patients with neuroblastoma.

In many different murine models, the immunogenicity of tumor cells can be increased by transduction with a range of immunostimulatory genes, inducing an immune response that causes regression of pre-existing unmodified tumor cells. To investigate the relevance of these animal models to pediatric malignancy, we used autologous unirradiated tumor cells transduced with an adenovirus-IL-2 to immunize 10 children with advanced neuroblastoma. In a dose-escalation study, we found that this tumor immunogen induced a moderate local inflammatory response consisting predominantly of CD4(+) T lymphocytes, and a systemic response, with a rise in circulating CD25(+) and DR+ CD3(+) T cells. Patients also made a specific antitumor response, manifest by an IgG antitumor antibody and increased cytotoxic T-cell killing of autologous tumor cells. Clinically, five patients had tumor responses after the tumor immunogen alone (one complete tumor response, one partial response, and three with stable disease). Four of these five patients were shown to have coexisting antitumor cytotoxic activity, as opposed to only one of the patients with nonresponsive disease. These results show a promising correlation between preclinical observations and clinical outcome in this disease, and support further exploration of the approach for malignant diseases of children.

Extensive cross-reactivity of adenovirus-specific cytotoxic T cells.

Although adenovirus is a major source of morbidity for immunocompromised individuals and a popular vector for gene therapy, little is known about the cellular immune responses it evokes in humans. Initial trials using adenovirus vectors have been disappointing, probably owing both to a preexisting immune response to Ad2 and Ad5, the most commonly used vector backbones, and to a response to the transgene. The former problem might be overcome by switching from the common type C adenoviruses, of which Ad2 and Ad5 are members, to other less common serotypes. Evidence for the feasibility of this approach has been provided by a rat model system. However, its success in humans depends on there being no immunological cross-reactivity between groups at the humoral or cellular level. Here, we examine the cross-reactivity of the cellular immune response to adenovirus in a human system, and find that human cytotoxic T lymphocytes (CTLs) prepared in vitro against an adenovirus from two of the six subgroups can lyse cells infected with adenoviruses from the other subgroups. Hence, the proposed use of adenovirus vectors from uncommon subgroups to evade memory immune response to subgroup C adenoviruses may not be successful. However, this same cross-reactivity indicates that adoptive transfer of CTLs generated in vitro against one adenovirus serotype may protect immunocompromised patients from infections by adenoviruses of all serotypes.

Cytotoxic T cells and immunotherapy.

Promising immunotherapies for viral infections and malignancies reflect the successful, rapid translation of laboratory findings into clinical practice. Fletcher et al. [1] present imaging studies of Epstein-Barr virus (EBV)-associated lymphomas before and after immunotherapy. Here, we briefly review the scientific bases of such novel therapies, which have evolved from advances in understanding of immune effector cells, of the cytokines that drive immune responses, and of the mechanisms underlying cell death.

Minimal residual disease after intensive induction therapy in childhood acute lymphoblastic leukemia predicts outcome.

We investigated the level of minimal residual disease (MRD) in 26 children with B-lineage acute lymphoblastic leukemia (ALL) after intensive induction therapy. A quantitative semi-nested polymerase chain reaction (PCR) detecting the clone-specific rearranged immunoglobulin heavy chain genes was developed to improve sensitivity and specificity of amplification. In all patients, one leukemic cell could be detected in a background of 10(5) normal blood mononuclear cells. All patients investigated were in complete remission at the end of induction therapy as evaluated by morphologic criteria. Nineteen patients (73%) had no detectable residual leukemic cells using the sensitive semi-nested PCR. Seven patients (27%) were PCR positive. Three had a low level (<2 x 10(-5) leukemic cells per bone marrow cell), while four patients had a high level (>2 x 10(5)) of detectable residual leukemic cells. All patients with low or undetectable levels of residual leukemia remained in complete remission at a median of 63 months from diagnosis (range 40-80 months), while all four patients with a high level of residual leukemia subsequently relapsed at a median of 21 months from diagnosis (range 13-37 months). The patient groups with undetectable or low, and high level of MRD did not differ significantly in other clinical or genetic features with prognostic significance. We conclude that the level of MRD at the end of the intensive induction therapy period is predictive of outcome in childhood B lineage ALL. If confirmed by large prospective studies, the level of MRD might be useful in stratifying patients into high and low risk categories.

Mutations in the mu heavy-chain gene in patients with agammaglobulinemia.

BACKGROUND: Most patients with congenital hypogammaglobulinemia and absent B cells are males with X-linked agammaglobulinemia, which is caused by mutations in the gene for Bruton's tyrosine kinase (Btk); however, there are females with a similar disorder who do not have mutations in this gene. We studied two families with autosomal recessive defects in B-cell development and patients with presumed X-linked agammaglobulinemia who did not have mutations in Btk. METHODS: A series of candidate genes that encode proteins involved in B-cell signal-transduction pathways were analyzed by linkage studies and mutation screening. RESULTS: Four different mutations were identified in the mu heavy-chain gene on chromosome 14. In one family, there was a homozygous 75-to-100-kb deletion that included D-region genes, J-region genes, and the mu constant-region gene. In a second family, there was a homozygous base-pair substitution in the alternative splice site of the mu heavy-chain gene. This mutation would inhibit production of the membrane form of the mu chain and produce an amino acid substitution in the secreted form. In addition, a patient previously thought to have X-linked agammaglobulinemia was found to have an amino acid substitution on one chromosome at an invariant cysteine that is required for the intrachain disulfide bond and, on the other chromosome, a large deletion that included the immunoglobulin locus. CONCLUSIONS: Defects in the mu heavy-chain gene are a cause of agammaglobulinemia in humans. This implies that an intact membrane-bound mu chain is essential for B-cell development.

Adenovirus-pulsed dendritic cells stimulate human virus-specific T-cell responses in vitro.

Adenovirus infections cause significant morbidity and mortality in immunocompromised patients, yet little is known about the immune response to adenovirus infections. We established a system for the generation of a cytotoxic immune response to adenovirus in vitro. Cytotoxic T cells (CTLs) were derived from normal donors by using peripheral blood dendritic cells as antigen-presenting cells. The CTLs were found to contain a mixture of effector cells that recognized virus peptides in the context of both class I and class II antigens. Endogenous viral gene expression was not required to sensitize cells to lysis by adenovirus-specific CTLs. CTLs raised against subgroup C adenovirus type 5 can lyse cells infected with subgroup B adenovirus type 11, indicating that viruses of different subgroups have epitopes in common. This system holds promise for defining the human immune response to adenovirus, including characterization of the viral protein(s) against which the response is generated, and the identity of the effector cells. Such studies are in progress.

The clinical significance of residual disease in childhood acute lymphoblastic leukemia as detected by polymerase chain reaction amplification by antigen-receptor gene sequences.

The polymerase chain reaction (PCR) has been applied to detect occult leukemia cells in children with acute lymphoblastic leukemia who are otherwise considered in complete remission by traditional morphological examination of bone marrow specimens. To determine whether PCR provides unique prognostic information of use for the clinical investigator, we reviewed the 20 clinical studies published to date. From this review, it is evident that discrepancies exist for the detection of residual disease for patients who remain in complete remission and for those who relapse. However, because of the fundamentally different approaches used to apply the PCR method to each of these studies, an entirely different interpretation can be reached when critical technical factors are considered. The combined data from the various studies suggest that a consistent pattern for residual disease disappearance over many months exists for patients who remain in extended complete remission and a pattern of residual disease persistence and reappearance preceding clinical findings exists for the majority of those who ultimately relapse in the bone marrow.

Detection of minimal residual disease in all: biology, methods, and applications.

The PCR technique appears to be the most sensitive method for detecting residual disease in ALL and can be applied to a high percentage of cases by amplifying sequences of the antigen-receptor genes. The PCR studies to date suggest that this sensitive technique can detect residual disease in virtually all patients during the first year of treatment. The residual disease becomes undetectable in the majority of patients by the end of treatment; however, a subset of patients remain PCR positive at a time when therapy is electively discontinued. The development of a highly accurate quantitative PCR technique may allow the possibility of distinguishing the patterns of residual disease for patients who will be cured by treatment from those who relapse. If such a pattern can be discerned, then an immediate benefit for PCR monitoring will be that clinicians will have the opportunity to test whether treating patients at the time of 'molecular relapse' will help to improve the cure rate for this disease. The PCR studies of remission marrows at the end of treatment raise a number of questions about the biology of disease persistence in patients who remain in extended 'remission.' A commitment to obtaining and analyzing bone marrow specimens in patients who have completed therapy is necessary to discern whether novel strategies, such as immunomodulatory manipulations, are needed to control or eradicated residual disease in patients who have completed planned chemotherapy. Thus, the long-term benefit of residual disease monitoring by PCR may be a better understanding of the biology and definition of 'cure' in ALL.

Mutations in the adenovirus-encoded single-stranded DNA binding protein that result in altered accumulation of early and late viral RNAs.

Adenovirus encodes a 72-kDa single-stranded DNA binding protein (DBP) that is necessary for viral DNA replication and is involved in controlling viral RNA metabolism. Studies of temperature-sensitive (ts) and site-directed mutants of the DBP have identified at least four regions of the protein involved in binding to single-stranded DNA and hence in DNA replication. Two of the ts mutants, Ad2ts111A and Ad2ND1+ts23, are deficient in DNA binding and in supporting in vitro DNA replication. Their effects on viral RNA metabolism are presented here. At early and late times of infection, accumulation of RNAs from the viral E3 region is increased up to sevenfold in Ad2ts111A- and Ad2ND1+ts23-infected cells relative to wild-type virus. This effect is temperature-independent and seems to involve nuclear RNA stability. Steady-state levels of the viral E1B and E4 RNAs increase following the onset of viral DNA replication in cells infected by the wild-type virus, but not in cells infected by ts111A or ts23. The increase in E1B and E4 RNAs at late times of infection is due to a stabilization of the mRNA. The steady-state levels of L3 and L5 RNAs are two- to fourfold higher in cells infected with ts23 and ts111A than with wild-type virus. None of these differences were observed following infection of cells with a temperature-independent revertant of ts111, indicating that the mutations in the DBP were responsible for the phenotypes. However, for the E3 effect, the change brought about by the mutations in the DBP does not seem to be the result of a change in the normal function of the protein, as an essentially DBP-negative virus (Ad5d/802) shows no differences in E3 RNA metabolism compared to wild-type virus at early times of infection. These results demonstrate that mutation of amino acids 280 and 282 of the DBP significantly perturbs the normal regulation of viral RNA metabolism. These effects clearly differ from the phenotypes observed with adenoviruses containing mutations in other early genes and from those ascribed to the ts125 mutation by others. These results are discussed in terms of the mechanisms by which early and late viral RNA metabolism are controlled and the possible effects of the DBP mutations on them.

Monitoring residual disease in acute lymphoblastic leukemia: therapeutic implications.

The polymerase chain reaction (PCR) has been applied to detect occult leukemia (ALL) cells in patients with acute lymphoblastic leukemia who are otherwise considered in complete remission by traditional morphological examination of bone marrow specimens. The combined data from the clinical studies published to date suggest that a consistent pattern for residual disease disappearance over many months exists for patients who remain in complete remission for an extended period of time. Conversely, a pattern of residual disease persistence and reappearance preceding clinical findings exists for the majority of patients who ultimately relapse. The ability to detect residual ALL disease near the end of chemotherapy or after the completion of treatment in some patients who otherwise are deemed likely to be cured of their malignancy raises the possibility that mechanisms other than leukemia cell cytotoxicity are influencing the outcome for this disease.

Bidirectional transcription from the human immunoglobulin VH6 gene promoter.

The human immunoglobulin (Ig) heavy chain VH6 gene promoter contains an imperfect octamer (AgGCAAAT) and is not dependent on the Ig heavy chain enhancer for activity; reporter constructs containing this promoter are very active in non-B cells. In experiments designed to characterize regions upstream of the transcriptional start site that are important for promoter function, we produced a series of deletion constructs, including one containing sequences between -74 and -146. Surprisingly, this fragment had promoter activity in both orientations. Inspection of the VH6 promoter sequence indicated that there was a possible TATA box in the proper orientation upstream of the imperfect octamer. The -74 to -146 fragment functioned as a promoter in the reverse orientation in three B cell lines and in non-B (HeLa) cells, with a much higher level of activity seen in the HeLa cells. To determine if the promoter could work in both directions simultaneously, reporter genes were positioned up- and downstream of a VH6 promoter fragment. Reporter gene activity was found for both genes in B cells and HeLa cells. Using a reverse transcriptase-polymerase chain reaction procedure (RT-PCR), we found a transcript corresponding to sequences upstream of the VH6 promoter in RNA from both the lymphoblastoid cell line ML-1, which actively transcribes the VH6 promoter, and the REH cell line, which does not. No transcripts were found in the KB epithelial cell line. Two or three mRNA 5' ends were found that mapped between -137 to -143 from the authentic VH6 transcription site, 31-37 nucleotides upstream of the putative TATA box. Inspection of the sequence upstream of the VH6 promoter demonstrated the presence of an open reading frame capable of coding for 96 amino acids. The VH6 promoter represents the second Ig promoter with bidirectional activity.

Residual disease detection in multiple follow-up samples in children with acute lymphoblastic leukemia.

The polymerase chain reaction (PCR) is more sensitive than other methods for detecting residual leukemic cells, and it can be used to analyze the dynamics of the leukemic cell population during and after chemotherapy. Leukemia cells are identified among the normal cells through the use of a leukemic cell-specific signature, such as the junction formed following rearrangement of the immunoglobulin (Ig) or T-cell receptor (TCR) variable (V), diversity (D), and joining (J) regions. We cloned the rearranged Ig or TCR genes from leukemic cells at the time of diagnosis by regular recombinant DNA techniques, or following PCR amplification, and determined the leukemic cell-specific V(D)J junctions. Using oligonucleotides prepared to the unique junctional sequences, we have analyzed Southern blots of PCR-amplified Ig or TCR genes from 11 patients at the time of diagnosis, and in from three to 14 follow-up samples for periods ranging from 17 to 97 months. The level of detection of residual blast cells in these patients was usually on the order of 1 leukemic cell in 10(4) normal ones. Conditions for the hybridization and washing were individually adjusted so that the specificity of the probes was excellent. No residual leukemic cells were found in patients who remained in continuous complete remission at time points more than 6 months post-diagnosis. PCR detected impending relapse in four out of six cases, with PCR-detectable leukemic clones being present 2, 4, 13 and 20 months prior to clinical signs of the disease. Relapse occurred in two patients who lacked PCR evidence of leukemic blasts in marrow samples collected 2 and 6 months before clinical recurrence, respectively. The leukemic cells that persisted for 3 years after a relapse in a patient who remained in clinical remission during this time period eventually became undetectable by PCR.

Analysis of the imperfect octamer-containing human immunoglobulin VH6 gene promoter.

The octamer sequence ATGCAAAT is highly conserved in the promoter of immunoglobulin heavy and light chain genes and is one of the sequence motifs involved in the control of transcription of these genes. The promoter region of an human immunoglobulin heavy chain variable gene, the sole member of the VH6 gene family, was found to differ from other VH gene promoters: it contains neither the conserved octamer motif nor a heptamer sequence, and generally bears little resemblance to other VH gene transcriptional control regions. An imperfect octamer sequence with a single nucleotide substitution (AgGCAAAT) is located 108 bp upstream of the ATG translation start site, and 81 bp upstream of the transcription initiation site. We sought to determine which sequence elements within the VH6 promoter were responsible for transcription initiation by creating progressive deletions of a 1 kb fragment from this region and testing their ability to function as promoter elements in B and non-B cells (HeLa). The minimum fragment required for full promoter function was 110 bp, but a fragment with only 65 bp retained 30-50% activity in B cells. Similar levels of transcription were seen when the -146 bp promoter containing two point mutations in the imperfect octamer was tested. Mutation of a possible pyrimidine box sequence located downstream of the TATA box was shown to have only a minor effect (10-30%) on transcription when three nucleotides were changed. Surprisingly, CAT activity was not B cell-specific, as all constructs had virtually the same activity in several B cell lines and in HeLa cells. Removal of the TATA box led to a 50% reduction in CAT activity, and the region upstream of the TATA box functioned as a promoter in both orientations. The transcriptional activity of the VH6 promoter was virtually enhancer independent: only a minor increase was observed when the immunoglobulin or SV40 enhancer was added to the promoter construct. Electrophoretic mobility shift assays of transcription factor binding to the region around the imperfect octamer indicated that binding was weak when nuclear extracts from either B cells or HeLa cells were used. The amount of complex shifted was increased by mutating the imperfect octamer to a perfect one. Chimeras produced between the VH6 promoter and a B cell-specific promoter from a member of the human VH2 gene family demonstrated that the lack of tissue specificity was due to the absence of a repressor of non-B cell transcription in the VH6 promoter. These results indicate that the VH6 promoter is relatively simple, requiring little more than the TATA element and the imperfect octamer, and transcription from this promoter lacks B cell specificity and is not dependent on the enhancer element.

Immunoglobulin heavy chain gene VH-D junctional diversity at diagnosis in patients with acute lymphoblastic leukemia.

Acute lymphoblastic leukemia (ALL) represents the clonal outgrowth of transformed hematopoietic progenitor cells. We have found that blast cells in some cases of B-precursor cell ALL contain Ig heavy chain gene rearrangements with considerable diversity at the junctions of the variable (VH), diversity (D), and joining (JH) regions. This diversity consists of heterogeneous nucleotide sequences at the VH-D and, less frequently, the D-JH junctions. In two cases, different VH segments were attached to the same D-JH rearrangement. In all cases studied there was a much higher than expected frequency of nucleotide sequence changes in the VH segment. At least three mechanisms may produce these changes in different cases: (1) continuing rearrangement of the heavy chain gene, in some cases by VH addition to a preexisting D-JH; (2) VH replacement; and (3) an open-and-shut mechanism. These findings suggest that an active VDJ recombinase system is present at the time of transformation in a high percentage of ALLs. An active recombinase in the rapidly growing leukemic cell population could lead to genomic instability.

MKW, a novel hematopoietic antigen.

A novel hematopoietic antigen was identified using a murine monoclonal antibody raised against KG-1 cells. This antigen, termed MKW, was also detected on the surface of the monocytic cell line U937, but not on the K562, ML1, or HL-60 cell lines. On normal hematopoietic cells, the antigen is expressed on the surface of monocytic and myelocytic cells and on a subpopulation of B-cells. During normal hematopoiesis, the surface expression of MKW is greatest and occurs very early on monocytic cells. Alternatively, in myeloid cells, surface expression occurs later and cell maturation is correlated with increased surface expression. When U937 cells are induced to differentiate, surface expression is transiently up-regulated. Surface expression of MKW, however, does not appear to be an activation antigen since activation of purified T- or B-cells failed to increase MKW on the cell surface. Leukemic blasts from 22 of 80 children (27%) with acute myeloblastic leukemia and from 29 of 225 children (13%) with acute lymphoblastic leukemia expressed MKW on the cell surface. Although surface expression of MKW was absent on T-cell lines, peripheral T-cells, and most B-cells, the antigen was identified in the cytoplasm of some B-cells, T-cells, and cell lines. Immunoprecipitation studies showed that MKW is a 52-kDa protein whether expressed on the cell surface or in the cytoplasm, and it appears to be nonglycosylated. Furthermore, studies with phosphatidylinositol-phospholipase C suggested that MKW is not attached to a glycolipid anchor. The biochemical characterization of MKW and its pattern of expression are distinct from any of the previously identified CD groups or published antigens. Since this unique antigen has prognostic significance in leukemia and appears to be associated with cell differentiation, its exact role in hematopoiesis should be investigated.

A monoclonal antibody to a novel surface antigen, MKW, blocks the antiproliferative and differentiation effects of granulocyte-macrophagecolony-stimulating factor and vitamin D3.

A monoclonal antibody (MoAb) recognizes a novel 52-Kd cell protein (MKW) that is expressed on cells of the normal myelocytic and monocytic lineage, a subset of B cells, and the U937 cell line. Using the U937 cell line as a model, the MoAb (anti-MKW) was examined for its ability to inhibit the effects of differentiation-inducing factors. In the U937 cell line, recombinant human granulocyte-macrophage colony-stimulating factor (rhGM-CSF) inhibits cell proliferation, 12-O-tetradecanoylphorbol-13-acetate (TPA) inhibits proliferation and induces the early differentiation antigen CD11b, and vitamin D3 inhibits proliferation and induces both CD11b and the late differentiation antigen CD14. The antiproliferative and differentiation effects of rhGM-CSF and vitamin D3 on U937 cells were inhibited by the anti-MKW MoAb. Similar effects were seen when anti-MKW antibody was added 30 minutes before or 2 hours after rhGM-CSF or vitamin D3, suggesting that its effects are not mediated by blocking or binding to the receptors for these growth factors. The anti-MKW MoAb had no effect on TPA-induced differentiation in U937 cells, indicating that TPA exerts its effects through a pathway different from rhGM-CSF and vitamin D3. These results suggest that the MKW antigen is important in controlling the proliferation and differentiation of monocytic cells.

Prevalence of N-ras mutations in children with myelodysplastic syndromes and acute myeloid leukemia.

The ras proto-oncogene family encodes a group of 21 kDa nucleotide-binding proteins. Activating mutations of ras genes are associated with certain types of malignancies, indicating that they are related in some way to the malignant process. We have examined bone marrow cells from nine children with myelodysplastic syndromes (MDS) and 35 with acute myeloid leukemia (AML) for activating point mutations of ras genes by in vitro amplification using polymerase chain reaction (PCR), oligonucleotide hybridization and sequencing of PCR products. We found N-ras mutations in cells from 3 of 9 children (33%) with MDS and only 2 of 35 children with AML (6%; 95% confidence interval is 0.7-19%). All mutations the second nucleotide of codon 12 or the first nucleotide of codon 61 of N-ras. There was no apparent correlation with clinical or laboratory characteristics, including karyotype; however, an association of N-ras activation with the most aggressive type of MDS was noted. Among the patients with MDS, 2 of 6 with monosomy 7 had N-ras mutations; however, three children with monosomy 7 which presented with AML lacked ras mutations. One patient was studied at time of diagnosis of MDS and again after progression to AML. At the preleukemic stage of disease, an N-ras mutation was identified; however, after development of AML this mutation was not present in the leukemic clone. In conclusion, these data show that ras mutations, while not necessary for leukemic transformation, may be important for the initiation of preleukemias evolving into overt AML.

Functional changes in temperature-sensitive mutants of the adenovirus single-stranded DNA-binding protein are accompanied by structural alterations.

Adenovirus requires the virus-encoded single-stranded DNA-binding protein (DBP) to replicate its DNA. We have previously shown (M. Tsuji, P. C. van der Vliet, and G. R. Kitchingman, J. Biol. Chem. 266:16178-16187, 1991) that the inability of three temperature-sensitive (ts) mutant DBPs (Ad2+ ND1ts23, Ad2ts111A, and Ad5ts125) to support DNA replication at the nonpermissive temperature was associated with impaired ability to bind to DNA. In this study, we examined these mutant proteins for structural alterations that might be linked to the functional changes. All three ts mutants, but not the wild-type protein, showed different proteolytic cleavage patterns before and after heating at 40 degrees C (the nonpermissive temperature), suggesting a possible conformational change during heating. The Ad2+ND1ts23 and Ad2ts111A DBPs have single amino acid changes located in a putative zinc finger subdomain (positions 282 and 280). In the presence of zinc ions, these ts mutants showed significantly increased resistance to inactivation at 40 degrees C. Surprisingly, however, the stabilizing effect of zinc was also observed with the Ad5ts125DBP, which contains a mutation located more than 100 amino acids from the zinc finger. Other related metal ions, such as cobalt, cadmium, and mercury, did not protect the ts DBPs from inactivation at 40 degrees C. These results indicate that functional changes of the ts DBPs in DNA replication and DNA binding are accompanied by structural alterations in the protein and that zinc and the metal-binding subdomain may play an important role in the structure and/or function of the DBP.