Biodistribution of NX211, liposomal lurtotecan, in tumor-bearing mice.

Prolonging tumor exposure to topoisomerase I inhibitors has been correlated to enhance the efficacy of those agents. Lurtotecan, a water-soluble camptothecin analog, was formulated as a liposomal drug, NX211, to enhance the delivery of drug to tumors. Tumor-bearing mice were treated with either [14C]NX211 containing [14C]lurtotecan, [3H]NX211 containing [3H]phosphatidylcholine or [14C]lurtotecan, euthanized at selected times post-injection, and tissues, plasma, urine and feces were collected. These studies demonstrated that KB tumors of [14C]NX211-treated mice had approximately 70-fold greater concentrations of [14C]lurtotecan at 24 h, respectively, compared to concentrations of [14C]lurtotecan of the KB tumors of [14C]lurtotecan-treated mice. The area under curve (AUC) from 0 to 48 h of [14C]lurtotecan for the KB tumors of [14C]NX211-treated animals was over 17-fold greater than the AUC of [14C]lurtotecan for the tumors of [14C]lurtotecan-treated animals. Treatment with [3H]NX211 demonstrated that the lipid component continually accumulated over 24 h in the tissues. HPLC analysis of extracted material from tumors of [14C]NX211-treated mice showed that more than 95% of the radioactive material was intact [14C]lurtotecan. These findings are one of the keys justifying the development of a liposomal formulation of lurtotecan, which has the intent to increase tumor exposure and increase antitumor efficacy.

Oligoclonal expansion of intraepidermal T cells in psoriasis skin lesions.

CD8(+) T cell infiltration into the epidermis is thought to be a key event in the pathogenesis of psoriasis. A quantitative competitive polymerase chain reaction method was developed to examine the expression of T cell receptor beta chain variable region 2, 3, 6.1-3, 8, and 13.1 genes in the epidermis of psoriatic lesions. Paired epidermal samples and peripheral blood samples from five psoriasis patients were studied. The results demonstrated the expansion of T cell receptor beta chain variable region 3 (two patients), 8 (two patients), and/or 2 (one patient). Contrary to previous reports, neither beta chain variable region 6.1-3 nor beta chain variable region 13.1 subgroups were expanded in any of the lesions. DNA sequence analysis revealed dominant T cell clones observed in all expanded beta chain variable region families and heterogeneous populations and/or small clones observed in non-expanded beta chain variable region families. Using CDR3 length analysis to examine the complete beta chain repertoire of the infiltrating T cells in the lesional epidermis, we found that approximately 50% of the T cell receptor beta chain variable region families in each patient's lesion demonstrated abnormal CDR3 DNA length distribution, indicating the presence of monoclonal or oligoclonal T cell expansion. Together, the results show that among different patients, T cell oligoclonality is not restricted to a limited number of T cell receptor beta chain variable region families. In an attempt to identify the pathogenic T cells among the many expanded T cell clones in the lesions, we compared T cell receptor expansion in the lesional epidermis with non-lesional epidermis. Particular T cell receptor were found to be preferentially expanded in lesional epidermis and these lesion-specific T cell clones may be most important in the pathogenesis and development of psoriatic lesions.

Antitumor efficacy, pharmacokinetics, and biodistribution of NX 211: a low-clearance liposomal formulation of lurtotecan.

Lurtotecan is a clinically active water-soluble camptothecin analogue that has been formulated into a low-clearance unilamellar liposome, NX 211. Comparative studies between free drug and NX 211 have been performed assessing pharmacokinetics in nude mice, tissue distribution in tumor-bearing mice, and antitumor efficacy in xenografts. Compared with lurtotecan, NX 211 demonstrated a significant increase in plasma residence time and a subsequent 1500-fold increase in the plasma area under the drug concentration curve. The volume of distribution was also greatly restricted, suggesting altered tissue distribution. Evaluation of tissues 24 h after administration of either [14C]NX 211 or [14C]lurtotecan to ES-2 tumor-bearing mice demonstrated a 40-fold increase in radiolabeled compound in the tumors of NX 211-treated mice compared with mice treated with lurtotecan. In single-dose efficacy studies, NX 211 produced a consistent 3-fold or greater increase in therapeutic index compared with lurtotecan in both the KB and ES-2 xenograft models. When compared at equitoxic levels in repeat-dose efficacy studies, NX 211 generated durable cures lasting >60 days and a 2-8-fold increase in log10 cell kill, compared with lurtotecan and topotecan, respectively. Together, these data demonstrate that NX 211 has significant therapeutic advantage over lurtotecan and that the improved antitumor activity is consistent with increased exposure and enhanced drug delivery to tumor sites.

Association and dissociation of the tripeptidyl-peptidase II complex as a way of regulating the enzyme activity.

Tripeptidyl-peptidase II is an unusually large exopeptidase. The subunits (M(r) = 138,000) form an active complex with an M(r) > 10(6). This paper demonstrates that the complex can spontaneously dissociate in vitro into dimers which retain 110th of the original specific activity. The dissociated enzyme can reassociate at elevated temperatures, provided the protein concentration is sufficiently high. This reassociation was accompanied by a reactivation. The rate of reactivation was increased by the presence of competitive peptide inhibitors. It is speculated that association/dissociation may be a way of regulating the enzyme activity in vivo.

Tripeptidyl peptidases: enzymes that count.

Protein degradation is essential for the life and death of every cell. Proteins are broken down to their constitutive amino acids by a succession of peptidases, both in lysosomes and in the cytosol. Tripeptidyl-peptidases I and II are enzymes that can 'count to three' and release N-terminal tripeptides from oligopeptides generated by different endopeptidases. The tripeptides are then degraded by other exopeptidases to release amino acids and dipeptides. Mutations in tripeptidyl-peptidase I have recently been associated with a lysosomal storage disease, late infantile neuronal ceroid lipofuscinosis.

Characterization and cloning of tripeptidyl peptidase II from the fruit fly, Drosophila melanogaster.

We describe the characterization, cloning, and genetic analysis of tripeptidyl peptidase II (TPP II) from Drosophila melanogaster. Mammalian TPP II removes N-terminal tripeptides, has wide distribution, and has been identified as the cholecystokinin-degrading peptidase in rat brain. Size exclusion and ion exchange chromatography produced a 70-fold purification of dTPP II activity from Drosophila tissue extracts. The substrate specificity and the inhibitor sensitivity of dTPP II is comparable to that of the human enzyme. In particular, dTPP II is sensitive to butabindide, a specific inhibitor of the rat cholecystokinin-inactivating activity. We isolated a 4309-base pair dTPP II cDNA which predicts a 1354-amino acid protein. The deduced human and Drosophila TPP II proteins display 38% overall identity. The catalytic triad, its spacing, and the sequences that surround it are highly conserved; the C-terminal end of dTPP II contains a 100-amino acid insert not found in the mammalian proteins. Recombinant dTPP II displays the predicted activity following expression in HEK cells. TPP II maps to cytological position 49F4-7; animals deficient for this interval show reduced TPP II activity.

Structure-function studies of recombinant murine tripeptidyl-peptidase II: the extra domain which is subject to alternative splicing is involved in complex formation.

Tripeptidyl-peptidase II (TPP II) is an exopeptidase with a remarkably high native Mr (> 10(6)). Recently, an alternatively spliced, murine cDNA variant was identified which contains an additional 39 bp, encoding 13 amino acids in the C-terminal end of the protein. The two enzyme variants were expressed in human kidney 293 cells. Both types of subunit were found to form the active oligomers. In addition, subunits containing the extra 13 amino acids formed an even larger complex eluting in the void volume of a Sepharose CL-4B column. Thus, it appears that this sequence is important for aggregation of subunits.

Distribution of tripeptidyl-peptidase II in the central nervous system of rat.

Tripeptidyl-peptidase II (TPP II) is a high molecular weight serine peptidase which removes tripeptides from a free N-terminus of longer peptides. Since it had previously been demonstrated that the enzyme can inactivate enkephalins and dynorphins in vitro by removing the N-terminal Tyr-Gly-Gly peptide, we wanted to see whether TPP II could be involved in this process also in vivo. Therefore, the localization of TPP II in different cerebral regions of rat was investigated by immunoblot analysis and activity measurements. It could be shown that TPP II is relatively evenly distributed in the central nervous system of rat. This indicates that the physiological role of the enzyme is probably not a specific degradation of enkephalins, but rather pertains to the general turnover of proteins.

Epstein-Barr virus nuclear protein 3C modulates transcription through interaction with the sequence-specific DNA-binding protein J kappa.

The Epstein-Barr virus (EBV) nuclear protein 3C (EBNA 3C) is essential for EBV-mediated transformation of primary B lymphocytes, is turned on by EBNA 2, and regulates transcription of some of the viral and cellular genes which are regulated by EBNA 2. EBNA 2 is targeted to response elements by binding to the DNA sequence-specific, transcriptional repressor protein J kappa. We now show that EBNA 3C also binds to J kappa. EBNA 3C causes J kappa to not bind DNA or EBNA 2. J kappa DNA binding activity in EBV-transformed lymphoblastoid cells is consequently reduced. More than 10% of the EBNA 3C coimmunoprecipitated with J kappa from extracts of non-EBV-infected B lymphoblasts that had been stably converted to EBNA 3C expression. EBNA 3C in nuclear extracts from these cells (or in vitro-translated EBNA 3C) prevented J kappa from interacting with a high-affinity DNA binding site. Under conditions of transient overexpression in B lymphoblasts, EBNA 2 and EBNA 3C associated with J kappa and less EBNA 2 associated with J kappa when EBNA 3C was coexpressed in the same cell. EBNA 3C had no effect on the activity of a -512/+40 LMP1 promoter-CAT reporter construct that has two upstream J kappa sites, but it did inhibit EBNA 2 transactivation of this promoter. These data are compatible with a role for EBNA 3C as a "feedback" down modulator of EBNA 2-mediated transactivation. EBNA 3C could, in theory, also activate transcription by inhibiting the interaction of the J kappa repressor with its cognate DNA. The interaction of two viral transcriptional regulators with the same cell protein may reflect an unusually high level of complexity or stringency in target gene regulation.

Characterization of cDNA for murine tripeptidyl-peptidase II reveals alternative splicing.

Tripeptidyl-peptidase II (TPP II) is a cytosolic high-M(r) exopeptidase with an active site of the subtilisin type. This paper describes cloning of cDNA encoding murine TPP II. Four clones were isolated from a murine mastocytoma cDNA library and the 5'-end was isolated by use of 5'-RACE (rapid amplification of cDNA ends). A total of 4611 bp were isolated, including the complete coding region. The deduced amino acid sequence shows a 96% overall identity when compared with the previously cloned human TPP II. The remarkably high identity indicates that not only the catalytic domain, but almost the entire subunit, must be of functional importance. Alignment with subtilisin-like serine peptidases identified Asp44, His264 and Ser449 as the catalytic triad, thus defining an extra domain of approximately 200 amino acids between the catalytic Asp and His in TPP II as compared with other subtilases. In addition, it was demonstrated that different polyadenylation signals can be utilized, since two different clones with untranslated 3'-ends of 155 bp and 781 bp respectively have been isolated. Finally, one of the isolated clones contains an extra 39 bp insert encoding 13 amino acids, which implies alternative splicing of the mRNA.

Use of a dehydroalanine-containing peptide as an efficient inhibitor of tripeptidyl peptidase II.

Tripeptidyl peptidase II is an intracellular exopeptidase, which has been purified from rat liver and human erythrocytes. An efficient specific inhibitor was obtained through beta-elimination of phosphate from the phosphopeptide Arg-Ala-Ser(P)-Val-Ala. The dehydroalanine-containing peptide formed was a competitive inhibitor with a Ki of 0.02 +/- 0.01 microM. This study demonstrated that replacing a serine residue in a good inhibitor with a dehydroalanine residue reduced the Ki 45 times. It is proposed that dehydroalanine-containing peptides could be of interest in the development of inhibitors for other peptidases as well.

An Epstein-Barr virus with a 58-kilobase-pair deletion that includes BARF0 transforms B lymphocytes in vitro.

A family of Epstein-Barr virus (EBV)-encoded RNAs found in nasopharyngeal carcinoma cells is also present at low levels in some latently infected and growth-transformed B lymphocytes (P. R. Smith, Y. Gao, L. Karran, M. D. Jones, D. Snudden, and B. E. Griffin, J. Virol. 67:3217-3225, 1993). A molecular genetic approach using EBV recombinants was undertaken to evaluate the role of these transcripts in primary B-lymphocyte growth transformation and latent infection. Since the se transcripts arise from a 22-kbp segment of the EBV genome and construction of large deletion mutants is an improbable result after transfection of infected cells with an EBV DNA fragment with a large deletion mutation, a new approach was taken to make a recombinant with the DNA encoding all of the BARF0 RNAs deleted. The approach derives from a recently described strategy for making recombinants from five overlapping EBV cosmid-cloned DNAs (B. Tomkinson, E. Robertson, R. Yalamanchili, R. Longnecker, and E. Kieff, J. Virol. 67:7298-7306, 1993). A large segment of EBV DNA was deleted from the transfected cosmid DNAs by omitting a cosmid which included all of the DNA encoding the BARF0 RNA and by ligating the distal halves of the two flanking cosmids so as to create one cosmid which had ends that overlapped with the other two unaltered cosmids. EBV recombinants with 58 kbp including BARF0 deleted resulted from transfecting the three overlapping EBV DNA fragments into P3HR-1 cells and simultaneously inducing lytic replication of the endogenous, transformation-defective, P3HR-1 EBV. The endogenous P3HR-1 EBV provided lytic infection and packaging functions. EBV recombinants with intact transforming functions were then selected by infecting primary B lymphocytes and growing the resultant transformed cells in lymphoblastoid cell lines. The efficiency of incorporation of the deletion into transforming EBV recombinants was close to that of a known indifferent marker, the type 1 EBNA 3A gene, indicating the absence of significant selection against the deletion. Cells infected with the deleted recombinant grew similarly to those infected with wild-type recombinants and had a similar level of permissiveness for lytic EBV infection. Thus, the BARF0 transcript is not critical to primary B-lymphocyte growth transformation or to latent infection. This methodology is useful for constructing EBV recombinants which are specifically mutated at other sites in the three cosmids and is a step toward deriving a minimal transforming EBV genome.

Epstein-Barr virus recombinants from overlapping cosmid fragments.

Five overlapping type 1 Epstein-Barr virus (EBV) DNA fragments constituting a complete replication- and transformation-competent genome were cloned into cosmids and transfected together into P3HR-1 cells, along with a plasmid encoding the Z immediate-early activator of EBV replication. P3HR-1 cells harbor a type 2 EBV which is unable to transform primary B lymphocytes because of a deletion of DNA encoding EBNA LP and EBNA 2, but the P3HR-1 EBV can provide replication functions in trans and can recombine with the transfected cosmids. EBV recombinants which have the type 1 EBNA LP and 2 genes from the transfected EcoRI-A cosmid DNA were selectively and clonally recovered by exploiting the unique ability of the recombinants to transform primary B lymphocytes into lymphoblastoid cell lines. PCR and immunoblot analyses for seven distinguishing markers of the type 1 transfected DNAs identified cell lines infected with EBV recombinants which had incorporated EBV DNA fragments beyond the transformation marker-rescuing EcoRI-A fragment. Approximately 10% of the transforming virus recombinants had markers mapping at 7, 46 to 52, 93 to 100, 108 to 110, 122, and 152 kbp from the 172-kbp transfected genome. These recombinants probably result from recombination among the transfected cosmid-cloned EBV DNA fragments. The one recombinant virus examined in detail by Southern blot analysis has all the polymorphisms characteristic of the transfected type 1 cosmid DNA and none characteristic of the type 2 P3HR-1 EBV DNA. This recombinant was wild type in primary B-lymphocyte infection, growth transformation, and lytic replication. Overall, the type 1 EBNA 3A gene was incorporated into 26% of the transformation marker-rescued recombinants, a frequency which was considerably higher than that observed in previous experiments with two-cosmid EBV DNA cotransfections into P3HR-1 cells (B. Tomkinson and E. Kieff, J. Virol. 66:780-789, 1992). Of the recombinants which had incorporated the marker-rescuing cosmid DNA fragment and the fragment encoding the type 1 EBNA 3A gene, most had incorporated markers from at least two other transfected cosmid DNA fragments, indicating a propensity for multiple homologous recombinations. The frequency of incorporation of the nonselected transfected type 1 EBNA 3C gene, which is near the end of two of the transfected cosmids, was 26% overall, versus 3% in previous experiments using transfections with two EBV DNA cosmids. In contrast, the frequency of incorporation of a 12-kb EBV DNA deletion which was near the end of two of the transfected cosmids was only 13%.(ABSTRACT TRUNCATED AT 400 WORDS)

Assignment of the linkage group EAM-TYRP2-TPP2 to chromosome 11 in pigs by in situ hybridization mapping of the TPP2 gene.

Restriction fragment length polymorphisms are described for the genes coding for tripeptidyl peptidase II (TPP2) and tyrosinase related protein II (TYRP2) in pigs. A linkage group comprising these loci and the locus for blood group M (EAM) was established by two-point lod score analysis in a three-generation pedigree. Multipoint analysis indicated the linear order EAM-1.1-TYRP2-8.4-TPP2 (recombination distances are given as Kosambi cM). The linkage group was assigned to porcine chromosome 11--the first on this chromosome--through in situ hybridization mapping of the TPP2 gene. TPP2 is the first gene localized on this chromosome using in situ hybridization.

Localization of the human tripeptidyl peptidase II gene (TPP2) to 13q32-q33 by nonradioactive in situ hybridization and somatic cell hybrids.

We have assigned the human tripeptidyl peptidase II (TPP2) gene to chromosome region 13q32-q33 using two different methods. First, a full-length TPP2 cDNA was used as a probe on Southern blots of DNA from a panel of human/rodent somatic cell hybrids. The TPP2 sequences were found to segregate with the human chromosome 13. Second, fluorescence in situ hybridization analysis was performed with the same probe. This analysis supported the chromosome 13 localization and further refined it to region 13q32-q33.

Deletion of DNA encoding the first five transmembrane domains of Epstein-Barr virus latent membrane proteins 2A and 2B.

A recombinant Epstein-Barr virus (EBV) was constructed, with a positive-selection marker inserted at the site of a deletion of a DNA segment which encodes the first five transmembrane domains of LMP2A and LMP2B. Despite the mutation, the mutant recombinant EBV was able to initiate and maintain primary B-lymphocyte growth transformation in vitro. Cells transformed with the mutant recombinant were not different from wild-type virus transformants in initial or long-term outgrowth, sensitivity to limiting cell dilution, or serum requirement. Expression of EBNA1, EBNA2, EBNA3A, EBNA3C, and LMP1 and permissivity for lytic EBV infection were also unaffected by the LMP2 deletion mutation. These results complete the molecular genetic studies proving LMP2 is dispensable for primary B-lymphocyte growth transformation, latent infection, and lytic virus replication in vitro.

Epstein-Barr virus nuclear proteins EBNA-3A and EBNA-3C are essential for B-lymphocyte growth transformation.

Recombinant Epstein-Barr viruses (EBV) with a translation termination codon mutation inserted into the nuclear protein 3A (EBNA-3A) or 3C (EBNA-3C) open reading frame were generated by second-site homologous recombination. These mutant viruses were used to infect primary B lymphocytes to assess the requirement of EBNA-3A or -3C for growth transformation. The frequency of obtaining transformants infected with a wild-type EBNA-3A recombinant EBV was 10 to 15%. In contrast, the frequency of obtaining transformants infected with a mutant EBNA-3A recombinant EBV was only 1.4% (9 mutants in 627 transformants analyzed). Transformants infected with mutant EBNA-3A recombinant virus could be obtained only by coinfection with another transformation-defective EBV which provided wild-type EBNA-3A in trans. Cells infected with mutant EBNA-3A recombinant virus lost the EBNA-3A mutation with expansion of the culture. The decreased frequency of recovery of the EBNA-3A mutation, the requirement for transformation-defective EBV coinfection, and the inability to maintain the EBNA-3A mutation indicate that EBNA-3A is essential or critical for lymphocyte growth transformation and that the EBNA-3A mutation has a partial dominant negative effect. Five transformants infected with mutant EBNA-3C recombinant virus EBV were also identified and expanded. All five also required wild-type EBNA-3C in trans. Serial passage of the mutant recombinant virus into primary B lymphocytes resulted in transformants only when wild-type EBNA-3C was provided in trans by coinfection with a transformation-defective EBV carrying a wild-type EBNA-3C gene. A secondary recombinant virus in which the mutated EBNA-3C gene was replaced by wild-type EBNA-3C was able to transform B lymphocytes. Thus, EBNA-3C is also essential or critical for primary B-lymphocyte growth transformation.

The last seven transmembrane and carboxy-terminal cytoplasmic domains of Epstein-Barr virus latent membrane protein 2 (LMP2) are dispensable for lymphocyte infection and growth transformation in vitro.

Specifically mutated Epstein-Barr virus (EBV) recombinants which truncate latent membrane protein 2A (LMP2A) and LMP2B after 260 of 497 amino acids and after 141 of 378 amino acids, respectively, were constructed. Despite truncation before the last seven transmembrane domains and the carboxy terminus, the mutant recombinants were not altered in initiation of primary B-lymphocyte infection or growth transformation, in expression of nuclear protein 1 or 2 or LMP1, or in induction of lytic EBV replication. Cells transformed by mutant virus recombinants were not different from wild-type virus transformants in initial or long-term outgrowth, sensitivity to limiting cell dilution, serum requirement, or clonogenic growth in soft agar. Together with similar analyses of a mutation stopping translation of the LMP2A amino-terminal cytoplasmic domain, these results indicate that LMP2 is not required for primary B-lymphocyte infection in vitro.

Use of second-site homologous recombination to demonstrate that Epstein-Barr virus nuclear protein 3B is not important for lymphocyte infection or growth transformation in vitro.

Recombinant Epstein-Barr viruses with a stop codon inserted into the nuclear protein 3B (EBNA 3B) open reading frame were generated by second-site homologous recombination. These mutant viruses infected and growth transformed primary B lymphocytes, resulting in the establishment of lymphoblastoid cell lines (LCLs). Polymerase chain reaction analysis and Southern hybridizations with infected cell DNA demonstrated the presence of the mutant EBNA 3B and the absence of wild-type EBNA 3B. Immunoblot analysis of the LCLs with affinity-purified EBNA 3B antibodies confirmed the absence of EBNA 3B cross-reactive protein. Virus was reactivated from two of these infected LCLs and serially passaged through primary B lymphocytes. The newly infected cells contained only the mutant recombinant virus. No difference was noted between mutant and wild-type recombinants, derived in parallel, in latent (other than EBNA 3B) or lytic cycle-infected cell virus protein expression or in the growth of the latently infected transformed cell lines. These data indicate that the EBNA 3B protein is not critical for primary B-lymphocyte infection, growth transformation, or lytic virus infection in vitro.