Targeting HOX-PBX interactions causes death in oral potentially malignant and squamous carcinoma cells but not normal oral keratinocytes

The HOX proteins are an important family of transcription factors that control a wide array of functions in embryogenesis and the maintenance of normal tissue [1, 2]. Their dysregulation has been implicated in the development of a variety of cancers [3‐5], including oral squamous cell carcinoma (OSCC) and we have shown that these changes also occur in cells from potentially malignant oral lesions (PMOLs) [6, 7]. Recent studies have highlighted the therapeutic potential of inhibiting the interaction between HOX proteins and a common group of co-factors, the PBX proteins, using the synthetic peptide HXR9 [8]. The consistent phenotypic effect reported on inhibition of HOX-PBX interactions is induction of apoptosis that has been reported in a number of malignant cell types [9‐13]. This has been associated with upregulation of c-Fos protein, which, whilst most often regarded as a proto-oncogene, may in some circumstances be pro-apoptotic [14].

This project aimed to determine whether targeting HOX-PBX interactions has therapeutic potential in OSCCs and PMOLs by assessing the expression of PBX1 and PBX2 in PMOL and OSCC cells and investigating the effect of HOX-PBX inhibition on these cells and in normal oral keratinocytes.

Identification of effective molecularly based therapeutics is vital if similar breakthroughs are to be made in the treatment of OSCC as in other solid tumours such as breast cancer. The observation that dysregulation of HOX gene expression occurs early in the pathogenesis of OSCC makes this family of transcription factors an attractive therapeutic target [7]. The main challenge in targeting HOX genes is their functional redundancy and the relatively conserved DNA binding site, thus specifically targeting individual HOX genes is unlikely to be feasible. The discovery that many HOX genes (particularly paralogous groups 1–8) require co-factor binding for stable interaction with DNA opens the potential for interfering with this interaction pharmaceutically using the HXR9 peptide. The effects of HXR9 have been demonstrated in a number of solid malignancies in vitro and in vivo [9, 11, 12, 17]. In this paper, we demonstrate the sensitivity of oral cancer cells to this agent, similar to that reported for other cancers, but in addition, we demonstrate similar effects on cells derived from potentially malignant oral lesions and the lack of effect on normal oral keratinocytes. This measure of selectivity was not seen on comparison of breast cancer cell lines with MCF10A cells where the sensitivity of three of the five cell lines tested was no different from the non-malignant MCF10A cells [11].

The data also suggests that HOX-PBX inhibition may be an effective strategy to prevent the development of OSCC due to its selective toxicity in PMOL cells. This may have particular benefit in the treatment of large PMOLs, which are not amenable to surgery, and for the prevention of subsequent malignancies in patients who have already developed an upper aero-digestive tract malignancy. These are significant clinical issues in the management of patients with PMOLs and OSCC.

The sensitivity of PMOL and OSCC cells is correlated with HOX gene expression overall and the median expression of the individual clusters, most particularly HOXA cluster genes (paralogues 1–8). Despite modest variation in expression of PBX1 and PBX2, there is no relationship between this and the EC50 of HXR9 in these cells. Presumably, this indicates that PBX co-factors are present in excess and as such, it is the aberrant expression of HOX genes in OSCC pathogenesis that confers the specificity. There was no effect on NOKs at the concentrations tested.

The mechanism of cell death induced by HXR9 has been demonstrated to be apoptosis in other solid malignancies [9, 11, 12, 17]. Similarly, we found that treatment of PMOL and OSCC cells with HXR9 resulted in induction of apoptosis with a significant increase in the number of cells in late apoptosis (Fig. 3).

HXR9 also increased c-Fos expression, which has been reported in other tumours, such as melanoma and prostate cancer [8, 10] (Fig. 4). Whilst mRNA expression increased markedly after HXR9 treatment, the increase in the expression of c-Fos protein is less consistent. Both the mRNA transcript and protein products are short lived and undergo rapid degradation. This indicates that further studies are required on the dynamics of c-Fos expression in these cells after treatment with HXR9.

These data demonstrate the therapeutic potential of HOX-PBX inhibitors not only in OSCC, but also in PMOLs, suggesting a wide range of possible therapeutic uses. This is a specific effect on cells with dysregulated HOX gene expression and iNOKs are not affected.