UNC-51/ATG1 kinase regulates axonal transport by mediating motor-cargo assembly.

Axonal transport mediated by microtubule-dependent motors is vital for neuronal function and viability. Selective sets of cargoes, including macromolecules and organelles, are transported long range along axons to specific destinations. Despite intensive studies focusing on the motor machinery, the regulatory mechanisms that control motor-cargo assembly are not well understood.

Spatial distribution and function of sterol regulatory element-binding protein 1a and 2 homo- and heterodimers by in vivo two-photon imaging and spectroscopy fluorescence resonance energy transfer.

Sterol regulatory element-binding proteins (SREBPs) are a subfamily of basic helix-loop-helix-leucine zipper proteins that regulate lipid metabolism. We show novel evidence of the in vivo occurrence and subnuclear spatial localization of both exogenously expressed SREBP-1a and -2 homodimers and heterodimers obtained by two-photon imaging and spectroscopy fluorescence resonance energy transfer. SREBP-1a homodimers localize diffusely in the nucleus, whereas SREBP-2 homodimers and the SREBP-1a/SREBP-2 heterodimer localize predominantly to nuclear speckles or foci, with some cells showing a diffuse pattern.

Association between promyelocyte protein and small ubiquitin-like modifier protein and the progression of cervical neoplasia.

Objective: To examine the association between the size and number of promyelocyte protein-containing nuclear bodies, their colocalization with the small ubiquitin-like modifier protein, and existing histopathologic staging of cervical neoplasia progressing toward squamous cell carcinoma.

Methods: Fluorescence-based immunodetection of the promyelocyte protein and the small ubiquitin-like modifier protein was performed on paraffin-embedded and histopathologically graded human uterine cervical tissues. Quantitative measurements of the size and number of the promyelocyte protein-containing nuclear bodies were made and statistically analyzed.

Spectroscopic approach for monitoring two-photon excited fluorescence resonance energy transfer from homodimers at the subcellular level.

We have employed a spectroscopic approach for monitoring fluorescence resonance energy transfer (FRET) in living cells. This method provides excellent spectral separation of green fluorescent protein (GFP) mutant signals within a subcellular imaging volume using two-photon excited fluorescence imaging and spectroscopy (TPIS-FRET). In contrast to current FRET-based methodologies, TPIS-FRET does not rely on the selection of optical filters, ratiometric image analysis, or bleedthrough correction algorithms.