High-Content Analysis of the Golgi Complex by Correlative Screening Microscopy

Quantifying Golgi Apparatus Fragmentation Using Imaging Flow Cytometry

Unlike the common conception of the Golgi apparatus as a static organelle, it is, in fact, a dynamic structure, as well as a sensitive sensor for the cellular status. In response to various stimuli, the intact Golgi structure undergoes fragmentation. This fragmentation can yield either partial fragmentation, resulting in several separated chunks, or complete vesiculation of the organelle. These distinct morphologies form the basis of several methods for the quantification of the Golgi status. In this chapter, we describe our imaging flow cytometry-based method for quantifying changes in the Golgi architecture. This method has all the benefits of imaging flow cytometry-namely, it is rapid, high-throughput, and robust-while affording easy implementation and analysis capabilities.

METTL3-mediated RNA m6A Hypermethylation Promotes Tumorigenesis and GH Secretion of Pituitary Somatotroph Adenomas

INTRODUCTION

Pituitary growth hormone-secreting (GH) pituitary adenomas (PAs) cause mass effects and dysregulated hypersecretion of GH. However, somatic mutation burden is low in PAs. While progress has been made in identifying the epigenetic changes involved in GH-PA initiation, the precise details of its tumorigenesis in GH-PA patients remains to be elucidated. As N6-methyladenosine (m6A) has been shown to often play a critical role in various tumors, it represents a possible initiation point for the tumorigenesis of pituitary adenomas. However, the role of RNA methylation in GH adenomas remains unclear.

METHODS

Protein expression of m6A regulators was measured by immunohistochemistry. Global levels and distribution of m6A methylation were separately analyzed by m6A enzyme-linked immunosorbent assay and m6A sequencing (m6A-seq). RNA interference and lentivirus knockdown system were used to investigate the role of methyltransferase-like 3 (METTL3) and its m6A- dependent regulatory mechanism in tumor progression and GH secretion.

RESULTS

We show that both METTL3 messenger RNA and protein expression are elevated in GH-PA samples when compared with both normal pituitary tissue specimens and nonsecreting pituitary adenomas. Levels of m6A modification increased in GH-PAs, and hypermethylated RNAs are involved in hormone secretion and cell development. Knockdown of METTL3 in GH3 cell line resulted in decreased cell growth and GH secretion. Importantly, we found that GNAS and GADD45γ act as the downstream targets in this process.

CONCLUSION

Our findings strongly suggest that m6A methyltransferase METTL3 promotes tumor growth and hormone secretion by increasing expression of GNAS and GADD45γ in a m6A-dependent manner. Thus, METTL3 and the methylated RNAs constitute suitable targets for clinical treatment of GH-PAs.

High Throughput Analysis of Golgi Structure by Imaging Flow Cytometry

The Golgi apparatus is a dynamic organelle, which regulates the vesicular trafficking. While cellular trafficking requires active changes of the Golgi membranes, these are not accompanied by changes in the general Golgi’s structure. However, cellular processes such as mitosis, apoptosis and migration require fragmentation of the Golgi complex. Currently, these changes are most commonly studied by basic immunofluorescence and quantified by manual and subjective classification of the Golgi structure in 100–500 stained cells. Several other high-throughput methods exist as well, but those are either complicated or do not provide enough morphological information. Therefore, a simple and informative high content methodology should be beneficial for the study of Golgi architecture. Here we describe the use of high-throughput imaging flow cytometry for quantification of Golgi fragmentation, which provides a simple way to analyze the changes in an automated, quantitative and non-biased manner. Furthermore, it provides a rapid and accurate way to analyze more than 50,000 cells per sample. Our results demonstrate that this method is robust and statistically powerful, thus, providing a much-needed analytical tool for future studies on Golgi dynamics, and can be adapted to other experimental systems.