Ultrasensitive in vivo bioassay detects bioactive human growth hormone in transduced primary human keratinocytes

An improved in vivo body weight gain bioassay for the potency determination of human growth hormone (hGH) has been set up in "little" mice (lit/lit), a mutant derived from the C57BL/6J strain. This improved assay now has a detection limit of the order of 0.05 micrograms/mouse/day, which corresponds to a sensitivity about 20-fold higher than that of the most sensitive in vivo assay reported up to now: the tibia test in hypophysectomized rats or mice. This sensitivity was achieved mainly by introduction of a careful pre-assay selection and of a three injections per day schedule. The utilization of these conditions in a 2x2 factorial assay design allowed the potency determination of recombinant DNA-derived hGH (rec-hGH) in bacterial extracts with acceptable accuracy and precision, together with the greatest economy of material, only 0.24 mg of unknown and standard hormone preparation being sufficient for an entire 10-animal assay. This contrasts to a minimum of 2.7 mg that are necessary for an economical assay in hypophysectomized rats. The same assay procedure was also used to demonstrate the in vivo bioactivity of hGH secreted into a culture medium from transduced human primary keratinocytes. The growth curve constructed with n = 8 little mice presented a highly significant correlation (r = 0.939, p < 0.001) and a slope = 0.016 g/mouse/day. It was thus possible to prove, for the first time, the in vivo bioactivity of rec-hGH secreted by transplantable human epidermal cells, utilized as an experimental model for somatic gene therapy

Clonal analysis of stably transduced human epidermal stem cells in culture.

We have transduced normal human keratinocytes with retroviral constructs expressing a bacterial beta-galactosidase (beta-gal) gene or a human interleukin-6 (hIL-6) cDNA under control of a long terminal repeat. Efficiency of gene transfer averaged approximately 50% and 95% of clonogenic keratinocytes for beta-gal and hIL-6, respectively. Both genes were stably integrated and expressed for more than 150 generations. Clonal analysis showed that both holoclones and their transient amplifying progeny expressed the transgene permanently. Southern blot analysis on isolated clones showed that many keratinocyte stem cells integrated multiple proviral copies in their genome and that the synthesis of the exogenous gene product in vitro was proportional to the number of proviral integrations. When cohesive epidermal sheets prepared from stem cells transduced with hIL-6 were grafted on athymic animals, the serum levels of hIL-6 were strictly proportional to the rate of secretion in vitro and therefore to the number of proviral integrations. The possibility of specifying the level of transgene expression and its permanence in a homogeneous clone of stem cell origin opens new perspectives in the long-term treatment of genetic disorders

Alpha melanocyte stimulating hormone (alpha MSH) stimulates normal human melanocyte growth by binding to high-affinity receptors

The combined action of cholera toxin (CT)-dependent activation of the adenylate cyclase signaling pathway, stimulation of protein kinase C, and activation of the tyrosine kinase activity of cell surface receptors and proto-oncogene products, have been shown to stimulate melanocyte proliferation. However, natural factors responsible for the optimal stimulation of normal human melanocyte growth, either isolated or co-cultured with keratinocytes, remain largely unknown. alpha MSH (alpha melanocyte stimulating hormone) has previously been shown to bind to murine and human melanoma cells and to stimulate their adenylate cyclase and tyrosinase activity. In contrast, very little is known about the presence and function of alpha MSH receptors in normal human melanocytes. We now report that alpha MSH: (i) binds to normal human melanocytes through a single class of high-affinity receptors; (ii) does not induce per se melanocytes to enter the S-phase of the cell cycle; (iii) does indeed stimulate melanocyte proliferation in a dose-dependent fashion; but its stimulatory effect requires bFGF and/or the activation of protein kinase C

Clonal analysis of stably transduced human epidermal stem cells in culture.

We have transduced normal human keratinocytes with retroviral constructs expressing a bacterial beta-galactosidase (beta-gal) gene or a human interleukin-6 (hIL-6) cDNA under control of a long terminal repeat. Efficiency of gene transfer averaged approximately 50% and 95% of clonogenic keratinocytes for beta-gal and hIL-6, respectively. Both genes were stably integrated and expressed for more than 150 generations. Clonal analysis showed that both holoclones and their transient amplifying progeny expressed the transgene permanently. Southern blot analysis on isolated clones showed that many keratinocyte stem cells integrated multiple proviral copies in their genome and that the synthesis of the exogenous gene product in vitro was proportional to the number of proviral integrations. When cohesive epidermal sheets prepared from stem cells transduced with hIL-6 were grafted on athymic animals, the serum levels of hIL-6 were strictly proportional to the rate of secretion in vitro and therefore to the number of proviral integrations. The possibility of specifying the level of transgene expression and its permanence in a homogeneous clone of stem cell origin opens new perspectives in the long-term treatment of genetic disorders

Nerve growth factor (NGF) binds to normal human keratinocytes through high and low affinity receptors and stimulates their growth by a novel autocrine loop.

Normal human keratinocytes synthesize and secrete biologically active nerve growth factor (NGF) in a growth regulated fashion (Di Marco, E., Marchisio, P. C., Bondanza, S., Franzi, A. T., Cancedda, R., and De Luca, M. (1991) J. Biol. Chem. 266, 21718-21722). Here we show that the same human keratinocytes bind NGF via low and high affinity receptors. In parallel with the course of NGF synthesis, the expression of low affinity NGF receptor (p75NGFr) decreases when a confluent, differentiated, and fully stratified epithelium is obtained. In skin sections, p75NGFr is present in basal keratinocytes and absent from suprabasal, terminally differentiated cells. The trkA protooncogene product (p140trkA), a component of the NGF receptor, is not expressed by keratinocytes. Instead, keratinocytes express a new member of the trk family (that we termed trkE), which generates 3.9-kilobase transcripts. Keratinocyte-derived NGF plays a key role in the autocrine epidermal cell proliferation. This has been proven by (i) direct effect of NGF on [3H]thymidine incorporation, (ii) inhibition of autocrine keratinocyte growth by monoclonal antibodies (alpha D11) inhibiting human NGF biological activity, and (iii) inhibition of autocrine keratinocyte proliferation by a trk-specific inhibitor, the natural alkaloid K252a. These data provide evidence that NGF, in addition to its effect as a survival and differentiation factor, is a potent regulator of cell proliferation, at least in human epithelial cells