Introduction of exogenous antigens into the MHC class I processing and presentation pathway by Drosophila antennapedia homeodomain primes cytotoxic T cells in vivo.

The homeodomain of the Antennapedia molecule (AntpHD) spontaneously crosses cellular membranes and can be used to deliver up to 50 additional amino acids to the cytoplasm. We exploited this approach to deliver antigenic peptides to the MHC class I processing and presentation pathway. AntpHD-based fusion peptides expressing the 170-179 HLA-Cw3 CTL epitope (pCw3) were produced in bacteria. Incubation of these fusion peptides with H-2d target cells resulted in efficient delivery to the cytosol as indicated by protease resistance and confocal microscopy. Moreover, this introduction of an exogenous Ag resulted in sensitization of the cell to lysis by a CTL clone specific for the 170-179 HLA-Cw3-derived peptide. Sensitivity of the Ag processing to brefeldin A but not to chloroquine is consistent with the delivery of AntpHD fusion peptides to the conventional class I-associated processing pathway. Immunization of DBA/2 (H-2d) mice with AntpHD pCw3 fusion peptide in the presence of SDS primed H-2Kd-restricted HLA-Cw3-specific CTL. Similar results were obtained with AntpHD fusion peptides expressing the 147-156 influenza nucleoprotein peptide. The strategy outlined in this paper provides a new approach for introducing molecules into the MHC class I Ag-presenting pathway. This approach has clear relevance to the design of synthetic peptide-based vaccines.

Transcription factor hoxa-5 is taken up by cells in culture and conveyed to their nuclei.

Homeoproteins are transcription factors known to be involved in the early patterning of the nervous system and in lineage decisions. While studying a possible role for homeoproteins at later stages of neuronal differentiation, we observed that the Antennapedia homeodomain is internalized by neurons, translocated to their nuclei, and enhances neurite outgrowth. Studies with mutant homeodomains showed that neurite elongation by post-mitotic vertebrate neurons is regulated by homeoproteins. An intriguing possibility suggested by these results, is that full length homeoproteins might be able to translocate through neuronal membranes. We now report that the entire Hoxa-5 homeoprotein is taken up by fibroblasts and neurons in culture and conveyed to their nuclei. Internalization occurs at 4 and 37 degrees C, and at concentrations as low as 10 pM compatible with a physiological mechanism.

The third helix of the Antennapedia homeodomain translocates through biological membranes.

The 60-amino acid long homeodomain of Antennapedia crosses biological membranes by an energy-independent mechanism, a phenomenon abolished by directed mutagenesis within the polypeptide C-terminal region. This finding led us to study the internalization of several chemically synthesized peptides derived from the third helix of the homeodomain. We report here that a polypeptide of 16 amino acids in length corresponding to the third helix of the homeodomain deleted of its N-terminal glutamate is still capable of translocating through the membrane. A longer peptide of 20 amino acids also translocates, whereas shorter peptides (15 amino acids) are not internalized by the cells. As is also the case for the entire homeodomain, the 20- and 16-amino acid long peptides are internalized at 4 degrees C, suggesting an energy-independent mechanism of translocation not involving classical endocytosis. The two translocated peptides can be recovered, intact, within the cells, strongly suggesting that they are not targeted to the lysosomal compartment. Finally, substitution of two tryptophans by two phenylalanines strongly diminishes translocation, raising the possibility that the internalization of the third helix is not solely based on its general hydrophobicity.

Neurotrophic activity of the Antennapedia homeodomain depends on its specific DNA-binding properties.

In previous reports we have demonstrated that the 60-aa peptide corresponding to the homeodomain of the Drosophila protein Antennapedia (pAntp) translocates through the membrane of neurons in culture, accumulates in neuronal nuclei, and promotes neurite growth. To analyze the importance of specific pAntp DNA-binding properties in this phenomenon we have constructed three mutant versions of pAntp that differ in their ability to translocate through the membrane and to bind specifically the cognate sequence for homeodomains present in the promoter of HoxA5. We demonstrate that removing two hydrophobic residues of the third helix inhibits pAntp internalization and suppresses its neurotrophic activity. We also show that pAntp neurotrophic activity is lost when mutations are introduced in positions preserving its penetration and nuclear accumulation but abolishing its capacity to bind specifically the cognate DNA-binding motif for homeoproteins. Our results strongly suggest that pAntp neurotrophicity requires both its internalization and its specific binding to homeobox cognate sequences. We propose that homeoproteins might regulate important events in the morphological differentiation of the postmitotic neuron.

Antennapedia homeobox peptide enhances growth and branching of embryonic chicken motoneurons in vitro.

Spinal motoneuron development is regulated by a variety of intrinsic and extrinsic factors. Among these, a possible role for homeoproteins is suggested by their expression in the motoneuron at relatively late stages. To investigate their possible involvement in motoneuron growth, we adapted a novel technique recently developed in this laboratory, based on the ability of the 60 amino acid-long homeobox of Antennapedia (pAntp) to translocate through the neuronal membrane and to accumulate in the nucleus (Joliot, A. H., C. Pernelle, H. Deagostini-Bazin, and A. Prochiantz. 1991. Proc. Natl. Acad. Sci. USA. 88:1864-1868; Joliot, A. H., A. Triller, M. Volovitch, C. Pernelle, and A. Prochiantz. 1991. New Biol. 3:1121-1134). Motoneurons from E5 chicken spinal cord were incubated with pAntp, purified by panning on SC1 antibody and plated on polyornithine/laminin substrata without further addition of pAntp. After 24 h, neurite outgrowth was already extensive in controls. In cultures of motoneurons that had been preincubated with 10(-7) M pAntp, neurite length was doubled; a similar effect was obtained using postnatal muscle extracts. Morphological analysis using a neurofilament marker specific for axons indicated that the homeobox peptide enhances primarily axonal elongation and branching. To test the hypothesis that the biological activity of pAntp involves its specific attachment to cognate homeobox binding sites present in the genome, we generated a mutant of pAntp called pAntp40P2, that was still able to translocate through the motoneuron membrane and to reach the nucleus, but had lost the specific DNA-binding properties of the wild-type peptide. Preincubation of pAntp40P2 with purified motoneurons failed to increase neurite outgrowth. This finding raises the possibility that motoneuron growth is controlled by homeobox proteins.

Control of neuronal morphogenesis by homeoproteins: consequences for the making of neuronal networks.

To test whether homeoproteins can act as genetic regulators in the processes of neurite growth, branching, guidance, and connectivity, the 60 amino acid homeodomain of Antennapedia was introduced in embryonic neurons in primary culture. It was hoped that this homeopeptide would bind to specific promoters and thus behave as a competitive inhibitor of endogenous homeoproteins. The introduction of the homeodomain in the nerve cells was made easy by its unexpected capability to translocate through the membranes and to accumulate within the nuclei. The presence of the homeodomain within the cells correlated with an increase in neurite growth and branching. The absence of activity of mutant peptides, still internalized but unable to bind with high affinity to homeoprotein cognate binding sites, strongly suggested that endogenous homeoproteins modulate neurite outgrowth and branching. Moreover, the efficient internalization of the homeobox peptide by live cells in culture raises the possibility that, in addition to their well-established role as cell-autonomous transcription factors, some homeoproteins may also exert paracrine functions. We examine how these hypotheses could modify our current views on the establishment and plasticity of neuronal networks.

alpha-2,8-Polysialic acid is the neuronal surface receptor of antennapedia homeobox peptide.

A synthetic peptide that is 60 amino acids in length and corresponds to the homeobox sequence of antennapedia protein (pAntp) is specifically and efficiently captured by neurons in culture and conveyed to their nuclei. The internalization process is followed by a strong induction of neuronal morphological differentiation. In the study described here, all treatments masking or removing the alpha-2,8-polysialic acid (PSA) chains specific to the neuronal cell adhesion molecule (NCAM) were found to block the penetration of pAntp and abolish its morphogenetic effects. Structural comparison between PSA and double-stranded DNA suggests that a sequence of eight sialic acid residues can mimic one large groove of the DNA. We propose that this structural similarity is the basis for the property of NCAM polysialic acid to participate in the internalization of the homebox polypeptide.