Tracking Tau in Neurons: How to Transfect and Track Exogenous Tau in Primary Neurons.

Primary murine neurons have proved to be an essential tool for the general investigation of neuronal polarity, polarized Tau distribution, and Tau-based neuronal dysfunction in disease paradigms. However, mature primary neurons are notoriously difficult to transfect with non-viral approaches and are very sensitive to cytoskeletal manipulation and imaging. Furthermore, standard non-viral transfection techniques require the use of a supportive glial monolayer or high-density cultures, both of which interfere with microscopy. Here we provide a simple non-viral liposome-based transfection method that enables transfection of Tau in low levels comparable to endogenous Tau. This allows the investigation of, for example, distribution and trafficking of Tau, without affecting other cytoskeleton-based parameters such as microtubule density or microtubule-based transport. Using this protocol, we achieve a profound transfection efficiency but avoid high overexpression rates. Importantly, this transfection method can be applied to neurons at different ages and is also suitable for very old cultures (up to 18 days in vitro). In addition, the protocol can be used in cultures without glial support and at suitable cell densities for microscopy-based single cell analysis. In sum, this protocol has proven a reliable tool suitable for most microscopy-based approaches in our laboratory.

Cultivation, Differentiation, and Lentiviral Transduction of Human-Induced Pluripotent Stem Cell (hiPSC)-Derived Glutamatergic Neurons for Studying Human Tau.

Tau pathology is a major hallmark of many neurodegenerative diseases summarized under the term tauopathies. In most of these disorders,  such as Alzheimer's disease, the neuronal axonal microtubule-binding Tau protein becomes mislocalized to the somatodendritic compartment. In human disease, this missorting of Tau is accompanied by an abnormally high phosphorylation state of the Tau protein, and several downstream pathological consequences (e.g., loss of microtubules, degradation of postsynaptic spines, impaired synaptic transmission, neuronal death). While some mechanisms of Tau sorting, missorting, and associated pathologies have been addressed in rodent models, few studies have addressed human Tau in physiological disease-relevant human neurons. Thus, suitable human-derived in vitro models are necessary. This protocol provides a simple step-by-step protocol for generating homogeneous cultures of cortical glutamatergic neurons using an engineered Ngn2 transgene-carrying WTC11 iPSC line. We further demonstrate strategies to improve neuronal maturity, that is, synapse formation, Tau isoform expression, and neuronal activity by co-culturing hiPSC-derived glutamatergic neurons with mouse-derived astrocytes. Finally, we describe a simple protocol for high-efficiency lentiviral transduction of hiPSC-derived neurons at almost all stages of differentiation.

Tracking Tau in Neurons: How to Grow, Fix, and Stain Primary Neurons for the Investigation of Tau in All Developmental Stages.

Primary murine neurons are a well-established tool for investigating Tau in the context of neuronal development and neurodegeneration. However, culturing primary neurons is usually time-consuming and requires multiple feeding steps, media exchanges, proprietary media supplements, and/or preparation of complex media. Here, we describe (i) a relatively cheap and easy cell culture procedure for the cultivation of forebrain neurons from embryonic mice (E13.5) based on a commercially available neuronal supplement (NS21), (ii) a protocol for the cultivation of hippocampal and cortical neurons from postnatal (P0-P3) animals, and (iii) basic fixation and immunofluorescence techniques for the staining of neuronal markers and endogenous Tau. We demonstrate a staining technique, which minimizes antibody consumption and allows for fast and convenient processing of samples for immunofluorescence microscopy of endogenous Tau in primary neurons. We also provide a protocol that enables cryopreservation of fixed cells for years without measurable loss of Tau signal. In sum, we provide reliable protocols enabling microscopy-based studies of Tau in primary murine neurons.

Differentiating SH-SY5Y Cells into Polarized Human Neurons for Studying Endogenous and Exogenous Tau Trafficking: Four Protocols to Obtain Neurons with Noradrenergic, Dopaminergic, and Cholinergic Properties.

Pathological alterations of the neuronal Tau protein are characteristic for many neurodegenerative diseases, called tauopathies. To investigate the underlying mechanisms of tauopathies, human neuronal cell models are required to study Tau physiology and pathology in vitro. Primary rodent neurons are an often used model for studying Tau, but rodent Tau differs in sequence, splicing, and aggregation propensity, and rodent neuronal physiology cannot be compared to humans. Human-induced pluripotent stem cell (hiPSC)-derived neurons are expensive and time-consuming. Therefore, the human neuroblastoma SH-SY5Y cell line is a commonly used cell model in neuroscience as it combines convenient handling and low costs with the advantages of human-derived cells. Since naïve SH-SY5Y cells show little similarity to human neurons and almost no Tau expression, differentiation is necessary to obtain human-like neurons for studying Tau protein-related aspects of health and disease. As they express in principle all six Tau isoforms seen in the human brain, differentiated SH-SY5Y-derived neurons are suitable for investigating the human microtubule-associated protein Tau and, for example, its sorting and trafficking. Here, we describe and discuss a general cultivation procedure as well as four differentiation methods to obtain SH-SY5Y-derived neurons resembling noradrenergic, dopaminergic, and cholinergic properties, based on the treatment with retinoic acid (RA), brain-derived neurotrophic factor (BDNF), and 12-O-tetrade canoylphorbol-13-acetate (TPA). TPA and RA-/TPA-based protocols achieve differentiation efficiencies of 40-50% after 9 days of treatment. The highest differentiation efficiency (~75%) is accomplished by a combination of RA and BDNF; treatment only with RA is the most time-efficient method as ~50% differentiated cells can be obtained already after 7 days.