Inhibition of T lymphocyte activation in mice heterozygous for loss of the IMPDH II gene.

Inosine 5'-monophosphate dehydrogenase (IMPDH) is the rate-limiting enzyme in the de novo synthesis of guanine nucleotides, which are also synthesized from guanine by a salvage reaction catalyzed by the X chromosome-linked enzyme hypoxanthine-guanine phosphoribosyltransferase (HPRT). Since inhibitors of IMPDH are in clinical use as immunosuppressive agents, we have examined the consequences of knocking out the IMPDH type II enzyme by gene targeting in a mouse model. Loss of both alleles of the gene encoding this enzyme results in very early embryonic lethality despite the presence of IMPDH type I and HPRT activities. Lymphocytes from IMPDH II(+/-) heterozygous mice are normal with respect to subpopulation distribution and respond normally to a variety of mitogenic stimuli. However, mice with an IMPDH II(+/-), HPRT(-/o) genotype demonstrate significantly decreased lymphocyte responsiveness to stimulation with anti-CD3 and anti-CD28 antibodies and show a 30% mean reduction in GTP levels in lymphocytes activated by these antibodies. Furthermore, the cytolytic activity of their T cells against allogeneic target cells is significantly impaired. These results demonstrate that a moderate decrease in the ability of murine lymphocytes to synthesize guanine nucleotides during stimulation results in significant impairment in T-cell activation and function.

Association of terminal deoxynucleotidyl transferase with Ku.

Terminal deoxynucleotidyl transferase (TdT) catalyzes the addition of nucleotides at the junctions of rearranging Ig and T cell receptor gene segments, thereby generating antigen receptor diversity. Ku is a heterodimeric protein composed of 70- and 86-kDa subunits that binds DNA ends and is required for V(D)J recombination and DNA double-strand break (DSB) repair. We provide evidence for a direct interaction between TdT and Ku proteins. Studies with a baculovirus expression system show that TdT can interact specifically with each of the Ku subunits and with the heterodimer. The interaction between Ku and TdT is also observed in pre-T cells with endogenously expressed proteins. The protein-protein interaction is DNA independent and occurs at physiological salt concentrations. Deletion mutagenesis experiments reveal that the N-terminal region of TdT (131 amino acids) is essential for interaction with the Ku heterodimer. This region, although not important for TdT polymerization activity, contains a BRCA1 C-terminal domain that has been shown to mediate interactions of proteins involved in DNA repair. The induction of DSBs in Cos-7 cells transfected with a human TdT expression construct resulted in the appearance of discrete nuclear foci in which TdT and Ku colocalize. The physical association of TdT with Ku suggests a possible mechanism by which TdT is recruited to the sites of DSBs such as V(D)J recombination intermediates.

T-cell specific avian TdT: characterization of the cDNA and recombinant enzyme.

A cDNA clone coding for avian terminal deoxynucleotidyl transferase (TdT) has been isolated and sequenced. The size of this cDNA was 2545 bp with an open reading frame of 1521 bp and a predicted translation product of 58 kDa. Comparison of this TdT sequence with other known TdT sequences has revealed a very high degree of homology at both the DNA and predicted amino acid levels. The chicken TdT cDNA was expressed in a bacterial system and the protein was purified by affinity chromatography. The purified recombinant enzyme, with a specific activity of approximately 1700 U/mg protein, was significantly less active than TdTs from mammalian species. This finding correlates with the observation that TdT isolated from avian thymus has lower activity than that isolated from any mammalian thymus source. Northern blot hybridization analyses and reverse transcription PCR of RNA preparations were carried out with the chicken cDNA. The data generated from these experiments revealed that the TdT RNA was only expressed in the thymus and not in the bone marrow or the bursa of Fabricius during pre- and post hatching chicken development. These data suggest that while TdT is probably involved in N region addition in chicken T-cell receptor genes, it is unlikely to play a role in diversification of immunoglobulin genes.

Mutational analysis of residues in the nucleotide binding domain of human terminal deoxynucleotidyl transferase.

Human terminal deoxynucleotidyl transferase (TdT) was overexpressed in a baculovirus system. The pure recombinant enzyme was identical in size, activity, kinetic constants, and metal effects to native enzyme. Three amino acids, within either the putative nucleotide binding domain and part of a DNA polymerase consensus sequence, YGDTDSLF, or a TdT consensus sequence, GGFRRGK, were altered by site-directed mutagenesis. The four mutant forms of terminal transferase were also overexpressed in the baculovirus expression system and purified from Trichoplusia ni larvae by a monoclonal antibody affinity column and compared with wild-type enzyme with respect to thermostabilities, secondary structure, metal effects, and kinetic parameters. Three of the four mutants retained 3-16% of wild-type activity under varying metal conditions, and one of the mutants, D343E, consistently exhibited less than 0.2% of wild-type TdT activity with dATP and no activity with dGTP. All mutants had alterations in the Km for dATP. Variations in Km for dGTP were not as consistent. The Km for the other substrate, DNA initiator (dA)50) in the presence of dATP remained essentially the same as that of wild-type TdT for all mutants except D343E. The enzyme activity of all mutants was stimulated by Zn2+ at low concentrations, and this effect was diminished and reversed at higher concentrations of ZnSO4. All mutants still retained significant amounts of the secondary structure as measured by circular dichroism. These results indicated that the aspartic acid residue at position 343 is located at or near the active site and is critical for the nucleotide binding and catalytic activity.

Mutational analysis of active site residues of human adenosine deaminase.

Adenosine deaminase was overexpressed in a baculovirus system. The pure recombinant and native enzymes were identical in size, Zn2+ content, and activity. Five amino acids, in proximity to the active site, were replaced by mutagenesis. The altered enzymes were purified to homogeneity and compared to wild-type adenosine deaminase with respect to zinc content, enzymatic activity, and kinetic parameters. All but one of the alterations produced significant activity perturbations. Replacement of Cys262 produced a protein that retained at least 30-40% of wild-type activity. In contrast, replacements of His17, His214, His238, and Glu217 resulted in dramatic losses of enzyme activity. None of these mutants exhibited large variations in Km. The proteins produced from alterations of amino acids implicated in metal coordination were slightly activated by inclusion of Zn2+ throughout purification. These experiments confirm that in the active enzyme Zn2+ plays a critical role in catalysis, that a histidine or glutamate residue plays a mechanistic role in the hydrolytic deamination step, and that cysteine is not involved in the catalytic mechanism of adenosine deaminase. These data support the roles for these amino acid residues suggested from the x-ray structure of murine adenosine deaminase (Wilson, D. K., Rudolf, F. B., and Quicho, F. A. (1991) Science 252, 1278-1284).

Molecular cloning of the UMP synthase gene rudimentary-like from Drosophila melanogaster.

The rudimentary-like locus encodes UMP synthase, a bienzyme protein containing the last two enzyme activities of de novo pyrimidine biosynthesis: orotate phosphoribosyltransferase and orotidylate decarboxylase. This locus lies within chromosome region 93B. New mutations have been used to refine the 93B cytogenetic map and a chromosome walk has been executed to clone DNA from this region. DNA encoding UMP synthase was identified using mixed oligonucleotides which were based on sequences derived from conserved peptide tracts of the protein in other species. cDNA clones of the embryonic UMP synthase mRNA have been isolated and used to define the extent of genomic DNA sequences which encode the transcript. The embryonic RNA is approximately 1.75 kb in length.

Efficient, low-cost protein factories: expression of human adenosine deaminase in baculovirus-infected insect larvae.

Human adenosine deaminase (EC 3.5.4.4), a key purine salvage enzyme essential for immune competence, has been overproduced in Spodoptera frugiperda cells and in Trichoplusia ni (cabbage looper) larvae infected with recombinant baculovirus. The coding sequence of human adenosine deaminase was recombined into a baculovirus immediately downstream from the strong polyhedrin gene promoter. Approximately 60 hr after infection of insect cells with the recombinant virus, maximal levels of intracellular adenosine deaminase mRNA, protein, and enzymatic activity were detected. The recombinant human adenosine deaminase represented 10% of the total cellular protein and exhibited a specific activity of 70 units/mg of protein in crude homogenate. This specific activity is 70-350 times greater than that exhibited by the enzyme in homogenates of the two most abundant natural sources of human adenosine deaminase, thymus and leukemic cells. When the recombinant virus was injected into insect larvae, the maximum recombinant enzyme was produced 4 days postinfection and represented about 2% of the total insect protein with a specific activity of 10-25 units/mg of protein. The recombinant human adenosine deaminase was purified to homogeneity from both insect cells and larvae and demonstrated to be identical to native adenosine deaminase purified from human cells with respect to molecular weight, interaction with polyclonal anti-adenosine deaminase antibody, and enzymatic properties. A pilot purification yielded 8-9 mg of homogeneous enzyme from 22 larvae. The production of large quantities of recombinant human adenosine deaminase in insect larvae is inexpensive and rapid and eliminates the need for specialized facilities for tissue culture. This method should be applicable to large-scale production of many recombinant proteins.