Ultrastructural morphometry of mammary gland in transgenic and non-transgenic rabbits.

The mammary gland of transgenic animals has been used for the production of recombinant proteins of therapeutic and nutraceutical use. The objective of this study was to compare the ultrastructure of transgenic and non-transgenic rabbit mammary gland tissue. New Zealand White transgenic rabbits were obtained by breeding non-transgenic rabbits with transgenic founder rabbits containing a whey acidic protein-human factor VIII (WAP-hFVIII) transgene integrated into their genome. Samples of mammary gland tissue from lactating rabbit females were isolated by surgical procedures. These samples were examined by optical and electron microscopy and photographs were taken. Measurements of ultrastructural organelles were made from digital images of the mammary cells. No differences were found in the cellular structure of mammary tissue, but significant differences t((0.001)) in the relative volume of mitochondria and vacuoles between transgenic and non-transgenic mammary gland epithelium were observed.

Aneuploidy in the transgenic rabbit.

The aim of this study was to determine whether there are differences in the karyotypes between transgenic and non-transgenic or control rabbits. New Zealand White transgenic rabbits (F1 generation) were obtained after breeding of transgenic founder rabbits that were derived from single--SM--or double microinjection--DM--with a WAP-hFVIII transgene. C-metaphase plates were obtained from short-time culture of peripheral blood lymphocytes synchronized by the addition of colcemide. A significantly higher rate of aneuploidy was observed in c-metaphase spreads of transgenic (56-66%) rabbits, as compared to non-transgenic ones (28-38%) (P < 0.05; P < 0.01). The patterns of chromosome banding were identical in both groups of rabbits. No structural aberrations were revealed in either group. These findings demonstrate that transgenic rabbits have a higher frequency of numerical chromosomal aberrations in their peripheral blood lymphocytes than normal rabbits, but without apparent deleterious effects on health or reproduction.

DNA preparation method can influence outcome of transgenic animal experiments.

In our continuing quest to improve the efficiency of producing transgenic animals, we have compared the influence of two transgene purification techniques on the efficiency of creating transgenic sheep and mice. Three hundred eighty-seven sheep zygotes and 2,737 mouse zygotes were microinjected with one of four transgenes. Transgenes were isolated from plasmid sequences either by agarose gel electrophoresis followed by gel extraction or by a single step sodium chloride gradient fractionation technique. Four transgenic sheep and 61 transgenic mice were produced. Both sheep and mice embryos responded similarly to transgene preparation methods. Overall, pregnancy rate was higher for recipients that received embryos injected with NaCl purified DNA (mean +/- SEM: 64 +/- 7% vs. 38 +/- 7%). Furthermore, offspring per zygote transferred (NaCl, 22 +/- 3% vs. Gel, 12 +/- 3%) and transgenics born per zygote transferred (NaCl, 3.9 +/- 0.6% vs. Gel, 1.5 +/- 0.6%) were higher when the NaCl purified DNA was used. However, the proportion of offspring born that were identified as transgenic did not differ between transgene purification methods. Transgenes responded differently to methods of preparation. One of the four genes yielded a significantly higher proportion of transgenics when the transgene was prepared by NaCl purification. These data suggest that on average the NaCl gradient purification technique results in a higher embryo survival rate to term for both sheep and mice, but the technique has no influence on rate of transgene integration.

Transgenic pigs produce functional human factor VIII in milk.

Deficiency or abnormality of coagulation factor VIII (FVIII) causes a bleeding disorder called hemophilia A. Treatment involves FVIII concentrates prepared from pooled human plasma or recombinant FVIII (rFVIII) prepared from mammalian cell culture. The cost of highly purified FVIII or rFVIII is a major factor in hemophilia therapy and restricts prophylaxis. We have sought to generate a new source of rFVIII by targeting expression of the human FVIII cDNA to the mammary gland of transgenic pigs using the regulatory sequences of the mouse whey acidic protein gene. The identity of processed heterodimeric rFVIII was confirmed using specific antibodies, by thrombin digestion and activity assays. The secretion of as much as 2.7 micrograms/ml of rFVIII in milk was over tenfold higher than in normal plasma. Up to 0.62 U/ml of rFVIII was detected in an assay in which rFVIII restored normal clotting activity to FVIII-deficient human plasma.

Vitamin K-dependent protein production in transgenic animals.

Vitamin K-dependent proteins are currently purified from pooled human plasma or produced in mammalian cell culture systems by recombinant DNA technology. Transgenic animals may provide an additional expression system for the production of these therapeutic proteins. Mice have been used to test hybrid genes which direct the expression of recombinant factor IX and Protein C to the mammary gland. Transgenic livestock have also been created that secrete into milk fully active Protein C at 0.3 mg/mL, and factor IX at 0.2 mg/mL. Thus, it is feasible to develop genetically manipulated livestock for the industrial production of vitamin K-dependent proteins.

Secretion of human furin into mouse milk.

We have previously described the expression of the human proprotein convertase furin or paired basic amino acid-cleaving enzyme, in mice transgenic for paired basic amino acid-cleaving enzyme and human Protein C (HPC). Here we show 100-fold or higher expression of furin in the mammary gland, compared with endogenous furin. Furin and recombinant HPC were detected in the same regions of the mammary gland and regulated similar to the endogenous whey acidic protein. In addition to the expected intracellular localization, furin was secreted into the milk as an 80-kDa form lacking the transmembrane and cytoplasmic domains. Furin present at levels of up to 40,000 units/ml milk cleaved the t-butoxycarbonyl-RVRR-AMC substrate with a Km of 32 microM, and processed the recombinant HPC precursor at the appropriate sites. Surprisingly, the expression of an active protease was not toxic to the mammary gland. This is a rare example of an animal model secreting active truncated forms of a processing endoprotease into a bodily fluid.

Rate limitations in posttranslational processing by the mammary gland of transgenic animals.

Our studies in transgenic animal bioreactors sought to determine the rate limitations in posttranslational processing of recombinant human protein C (rhPC) made in mammary gland of mice and pigs. Human protein C (hPC) is a complex plasma protein containing nine gamma-carboxylated glutamic acid (gla) residues that bind calcium at about 1 to 3 mM. Gamma carboxylation is a vitamin K-dependent posttranslational modification. The effect of rhPC synthesis rate on the extent of gamma-carboxylation of glutamic acid was studied. We have perturbed the biosynthesis of rhPC by using two different transgenes to direct mammary gland-specific expression. Promoter elements of the murine whey acid protein (mWAP) gene were used to drive the expression of hPC-cDNA and hPC-genomic transgenes. Transgenic mice with hPC-cDNA and hPC-genomic sequences gave expression levels of 11 +/- 4 micrograms rhPC/ml of milk and 895 +/- 21 micrograms rhPC/ml of milk, respectively. Transgenic pigs with hPC-cDNA and hPC-genomic sequences gave expression levels of 100 to 500 micrograms rhPC/ml of milk and 800 to 2000 micrograms rhPC/ml of milk, respectively. A monoclonal antibody (7D7B10-mAb) that binds an epitope in the gla domain of hPC in the absence of calcium was used to study the conformational behavior of immunopurified rhPC. Immunopurified rhPC from lower expressing mice and pigs gave a calcium-dependent binding inhibition by 7D7B10-mAb similar to that of hPC. Immunopurified rhPC from higher expressing mice and pigs gave a less calcium-dependent response. This study suggests that a rate limitation in gamma-carboxylation by the mammary gland occurs at expression levels about > 20 micrograms/ml in mice and > 500 micrograms/ml in pigs.

Proteolytic maturation of protein C upon engineering the mouse mammary gland to express furin.

Endoproteolytic processing of the human protein C (HPC) precursor to its mature form involves cleavage of the propeptide after amino acids Lys-2-Arg-1 and removal of a Lys156-Arg157 dipeptide connecting the light and heavy chains. This processing was inefficient in the mammary gland of transgenic mice and pigs. We hypothesized that the protein processing capacity of specific animal organs may be improved by the coexpression of selected processing enzymes. We tested this by targeting expression of the human proprotein processing enzyme, named paired basic amino acid cleaving enzyme (PACE)/furin, or an enzymatically inactive mutant, PACEM, to the mouse mammary gland. In contrast to mice expressing HPC alone, or to HPC/PACEM bigenic mice, coexpression of PACE with HPC resulted in efficient conversion of the precursor to mature protein, with cleavage at the appropriate sites. These results suggest the involvement of PACE in the processing of HPC in vivo and represent an example of the engineering of animal organs into bioreactors with enhanced protein processing capacity.

Regulation of human protein C gene expression by the mouse WAP promoter.

A 4.1 kb mouse whey acidic protein (mWAP) promoter was cloned from a C57BL/6 cosmid library. The tissue-specific and developmental pattern of expression of a hybrid gene comprised of the mWAP promoter fragment and the human protein C (HPC) gene was analysed in transgenic mice. The corresponding RNA was detected mainly in the mammary gland, with 'leakage' of expression in the salivary gland and kidney. The developmental pattern of transgene expression differed from that of the endogenous WAP gene. In particular, recombinant HPC (rHPC) transcripts were detected earlier in pregnancy than WAP RNA, with no significant increase during lactation. This indicates that regulatory elements responsible for developmental regulation are located outside the 4.1 kb mWAP gene promoter fragment, or if present, may be subject to position effects. Precocious expression of the transgene did not compromise the health or nursing abilities of transgenic females. Expression of rHPC affected the appearance of the mammary alveoli and alveolar epithelial cells in lactating transgenic mice. The alveoli were less distended and alveolar epithelial cells appeared cuboidal with centrally positioned nuclei. We suggest that the inefficient intracellular processing of rHPC can alter the histological appearance of alveolar epithelial cells in the transgenic mammary gland.

Inefficient processing of human protein C in the mouse mammary gland.

Vitamin K-dependent plasma protein, human Protein C (HPC) has been expressed in transgenic mice, using a 4.2 kb mouse whey acidic protein (WAP) promoter, 9.0 kb HPC gene and 0.4 kb 3' flanking sequences. Expression was mammary gland-specific and the recombinant human Protein C (rHPC) was detected in milk at concentrations of 0.1 to 0.7 mg ml-1. SDS-PAGE revealed that the single, heavy and light chains of rHPC migrated with increased electrophoretic mobility, as compared to HPC. Enzymatic deglycosylation showed that these molecular weight disparities are in part due to differential glycosylation. The substantial increase observed in the amount of single chain protein, as well as the presence of the propeptide attached to 20-30% of rHPC, suggest that mouse mammary epithelial cells are not capable of efficient proteolytic processing of rHPC. The Km of purified rHPC for the S-2366 synthetic substrate was similar to that of plasma-derived HPC, while the specific activity was about 42-77%. Amino acid sequence analyses and low anticoagulant activity of purified rHPC suggest that gamma-carboxylation of rHPC is insufficient. These results show that proteolytic processing and gamma-carboxylation can be limiting events in the overexpression of fully biologically active rHPC in the mouse mammary gland.

The porcine mammary gland as a bioreactor for complex proteins.

The similar biological activity of rhPC and hPC indicates that porcine mammary gland can perform many of the processing reactions necessary for recombinant synthesis of complex human proteins and produce them at levels suitable for industrial bioreactor applications. The health of the transgenic pigs appeared unaffected by the expression of high levels of the heterologous protein. We suggest that one of the advantages of using the mammary gland as a bioreactor appears to be the high cell density relative to that of cell culture.