Molecule transfer into mammalian cells by single sub-nanosecond laser pulses.

A rapid, precise, and viability-retaining method for cytoplasmic molecule delivery is highly desired for cell engineering. Routine methods suffer from low throughput, lack of selectivity, requirement of helper compounds, predominant endosomal delivery, and/or are restricted to specific molecule classes. Photonic cell manipulation bears the potential to overcome these drawbacks. Here we investigated mammalian cell manipulation by single sub-nanosecond laser pulses. Axial beam waist positioning close to a cell monolayer induced culture vessel damage and zones of cell ablation. Cells at margins of ablation zones exhibited uptake of membrane-impermeant fluorophores and GFP expression plasmids. Increasing Rayleigh-length and beam waist diameter reduced the sensitivity to axial defocusing and resulted in robust molecule transfer. Serial application of single pulses focused over a moving cell monolayer yielded quantitative molecule transfer to cells at rates up to 40%. Our results could be basic to spatially and temporally controlled single laser pulse-mediated marker-free high throughput cell manipulation.

Aberrant splicing in several human tumors in the tumor suppressor genes neurofibromatosis type 1, neurofibromatosis type 2, and tuberous sclerosis 2.

Mutations at splice sites or surrounding sequences have been reported to cause aberrant splicing. However, splicing errors can also occur without sequence alterations. We investigated three tumor suppressor genes for aberrant splicing in tumors. At a low frequency per exon it was found in five of seven of the investigated in-frame exons of the neurofibromatosis type 1 (NF1) gene, in two of three exons of the neurofibromatosis type 2 (NF2) gene, and in one of three exons of the tuberous sclerosis 2 gene. It was detectable in all of the human tumor tissues tested (NF1 neurofibroma, sporadic intramedullar neurinoma, sporadic meningiomas, NF2 schwannoma, NF2 meningioma, basalioma, and naevus) as well as in cultured tumor cell lines and cultured primary cells. Hence, our data show that aberrant splicing is a very common process. According to simulations of the secondary structures of the pre-mRNA, we suggest that aberrant splicing is attributable to the rare occurrence of alternative structures at the splice donor site, which are not recognized by the splice machinery. In HeLa cells, aberrant splicing is found to be increased at elevated temperatures and low pH in vitro, conditions often found in tumor tissues. In three tumor tissues tested for one NF1 exon, we found approximately twice the amount of aberrant transcript as in normal tissues. Therefore, we suggest that the increase in aberrant splicing caused by environmental factors represents an additional mechanism for the reduction of the amount of tumor suppressor mRNA in the absence of relevant mutations in the tumor.

Matrix-dependent regulation of AKT in Hepsin-overexpressing PC3 prostate cancer cells.

The serine-protease hepsin is one of the most prominently overexpressed genes in human prostate carcinoma. Forced expression of the enzyme in mice prostates is associated with matrix degradation, invasive growth, and prostate cancer progression. Conversely, hepsin overexpression in metastatic prostate cancer cell lines was reported to induce cell cycle arrest and reduction of invasive growth in vitro. We used a system for doxycycline (dox)-inducible target gene expression in metastasis-derived PC3 cells to analyze the effects of hepsin in a quantitative manner. Loss of viability and adhesion correlated with hepsin expression levels during anchorage-dependent but not anchorage-independent growth. Full expression of hepsin led to cell death and detachment and was specifically associated with reduced phosphorylation of AKT at Ser(473), which was restored by growth on matrix derived from RWPE1 normal prostatic epithelial cells. In the chorioallantoic membrane xenograft model, hepsin overexpression in PC3 cells reduced the viability of tumors but did not suppress invasive growth. The data presented here provide evidence that elevated levels of hepsin interfere with cell adhesion and viability in the background of prostate cancer as well as other tissue types, the details of which depend on the microenvironment provided. Our findings suggest that overexpression of the enzyme in prostate carcinogenesis must be spatially and temporally restricted for the efficient development of tumors and metastases.