SCYL1 does not regulate REST expression and turnover

CRISPR-Cas9-mediated insertion of a short artificial intron for the generation of conditional alleles in mice

In this protocol, we describe the generation of conditional alleles in mice using the DECAI (DEgradation based on Cre-regulated Artificial Intron) approach. We detail steps for the CRISPR-mediated insertion of the short DECAI cassette within exon 3 of Scyl1 and the functional validation of alleles at genomic, transcriptomic, and protein levels. This strategy simplifies the process of generating mice with conditional alleles. For complete details on the use and execution of this protocol, please refer to Cassidy et al. (2022).1.

Novel methods for the generation of genetically engineered animal models

Genetically modified mouse models have shaped our understanding of biological systems in both physiological and pathological conditions. For decades, mouse genome engineering has relied on transgenesis and spontaneous gene replacement in embryonic stem (ES) cells. While these technologies provided a wealth of knowledge, they remain imprecise and expensive to use. Recent advances in genome editing technologies such as the development of targetable nucleases, the improvement of delivery systems, and the simplification of targeting strategies now allow for the rapid, precise manipulation of the mouse genome. In this review article, we discuss novel methods and targeting strategies for the generation of mouse models for the study of bone and skeletal muscle biology.

One-step generation of a conditional allele in mice using a short artificial intron

Despite tremendous advances in genome editing technologies, generation of conditional alleles in mice has remained challenging. Recent studies in cells have successfully made use of short artificial introns to engineer conditional alleles. The approach consists of inserting a small cassette within an exon of a gene using CRISPR-Cas9 technology. The cassette, referred to as Artificial Intron version 4 (AIv4), contains sequences encoding a splice donor, essential intronic sequences flanked by loxP sites and a splice acceptor site. Under normal conditions, the artificial intron is removed by the splicing machinery, allowing for proper expression of the gene product. Following Cre-mediated recombination of the two loxP sites, the intron is disabled, and splicing can no longer occur. The remaining intronic sequences create a frameshift and early translation termination. Here we describe the application of this technology to engineer a conditional allele in mice using Scyl1 as a model gene. Insertion of the cassette occurred in 17% of edited mice obtained from pronuclear stage zygote microinjection. Mice homozygous for the insertion expressed SCYL1 at levels comparable to wild-type mice and showed no overt abnormalities associated with the loss of Scyl1 function, indicating the proper removal of the artificial intron. Inactivation of the cassette via Cre-mediated recombination in vivo occurred at high frequency, abrogated SCYL1 protein expression, and resulted in loss-of-function phenotypes. Our results broaden the applicability of this approach to engineering conditional alleles in mice.

Overexpression of SCYL1 Is Associated with Progression of Breast Cancer

SCYL1 is a pseudokinase and plays roles in cell division and gene transcription, nuclear/cytoplasmic shuttling of tRNA, protein glycosylation, and Golgi morphology. However, the role of SCYL1 in human breast cancer progression remains largely unknown. In this study, we determined expression of SCYL1 in breast cancer by searching the Cancer Genome Atlas (TCGA) and Tumor Immunoassay Resource (TIMER) databases. Meanwhile, we collected breast tumor tissue samples from 247 cases and detected expression of SCYL1 in the tumors using the tissue microarray assay (TMA). Association of SCYL1 with prognosis of breast cancer was determined based on the PrognoScan database. The results have shown that SCYL1 is overexpressed in breast cancer, and the expression of SCYL1 is associated with poor clinical outcomes of breast cancer patients. Furthermore, knockdown of SCYL1 by shRNAs significantly inhibited the proliferation and migration of breast cancer cells. Taken together, our data suggest that SCYL1 is a biomarker for poor prognosis of breast cancer, has a promoting role in breast cancer progression, and is a potential target for breast cancer therapy.

mTORC1 controls Golgi architecture and vesicle secretion by phosphorylation of SCYL1

The protein kinase mechanistic target of rapamycin complex 1 (mTORC1) is a master regulator of cell growth and proliferation, supporting anabolic reactions and inhibiting catabolic pathways like autophagy. Its hyperactivation is a frequent event in cancer promoting tumor cell proliferation. Several intracellular membrane-associated mTORC1 pools have been identified, linking its function to distinct subcellular localizations. Here, we characterize the N-terminal kinase-like protein SCYL1 as a Golgi-localized target through which mTORC1 controls organelle distribution and extracellular vesicle secretion in breast cancer cells. Under growth conditions, SCYL1 is phosphorylated by mTORC1 on Ser754, supporting Golgi localization. Upon mTORC1 inhibition, Ser754 dephosphorylation leads to SCYL1 displacement to endosomes. Peripheral, dephosphorylated SCYL1 causes Golgi enlargement, redistribution of early and late endosomes and increased extracellular vesicle release. Thus, the mTORC1-controlled phosphorylation status of SCYL1 is an important determinant regulating subcellular distribution and function of endolysosomal compartments. It may also explain the pathophysiology underlying human genetic diseases such as CALFAN syndrome, which is caused by loss-of-function of SCYL1.

mTORC1 is a master regulator of cell growth with well-known functions in inhibiting autophagic vesicle formation. Here, the authors show that mTORC1 also affects Golgi architecture and vesicle secretion by phosphorylating the scaffold protein SCYL1.

Dissecting protein function in vivo: Engineering allelic series in mice using CRISPR-Cas9 technology

Allelic series are extremely valuable genetic tools to study gene function and identify essential structural features of gene products. In mice, allelic series have been engineered using conventional gene targeting in embryonic stem cells or chemical mutagenesis. While these approaches have provided valuable information about the function of genes, they remain cumbersome. Modern approaches such as CRISPR-Cas9 technologies now allow for the precise and cost-effective generation of mouse models with specific mutations, facilitating the development of allelic series. Here, we describe procedures for the generation of three types of mutations used to dissect protein function in vivo using CRISPR-Cas9 technology. This step-by-step protocol describes the generation of missense mutations, large in-frame deletions, and insertions of genetic material using SCY1-like 1 (Scyl1) as a model gene.

SCYL1 disease and liver transplantation diagnosed by reanalysis of exome sequencing and deletion/duplication analysis of SCYL1

SCYL1 disease results from biallelic pathogenic variants in SCYL1. We report two new patients with severe hepatic phenotype requiring liver transplantation. Patient charts reviewed. DNA samples and skin fibroblasts were utilized. Literature was reviewed. 13-year-old boy and 9-year-old girl siblings had acute liver insufficiency and underwent living related donor liver transplantation in infancy with no genetic diagnosis. Both had tremor, global developmental delay, and cognitive dysfunction during their follow-up in the medical genetic clinic for diagnostic investigations after their liver transplantation. Exome sequencing identified a likely pathogenic variant (c.399delC; p.Asn133Lysfs*136) in SCYL1. Deletion/duplication analysis of SCYL1 identified deletions of exons 7-8 in Patient 1. Both variants were confirmed in Patient 2 and the diagnosis of SCYL1 disease was confirmed in both patients at the age of 13 and 9 years, respectively. SCYL1 protein was not expressed in both patients' fibroblast using western blot analysis. Sixteen patients with SCYL1 disease reported in the literature. Liver phenotype (n = 16), neurological phenotype (n = 13) and skeletal phenotype (n = 11) were present. Both siblings required liver transplantation in infancy and had variable phenotypes. Exome sequencing may miss the diagnosis and phenotyping of patients can help to diagnose patients.

Overlapping Role of SCYL1 and SCYL3 in Maintaining Motor Neuron Viability

Members of the SCY1-like (SCYL) family of protein kinases are evolutionarily conserved and ubiquitously expressed proteins characterized by an N-terminal pseudokinase domain, centrally located Huntingtin, elongation factor 3, protein phosphatase 2A, yeast kinase TOR1 repeats, and an overall disorganized C-terminal segment. In mammals, three family members encoded by genes Scyl1, Scyl2, and Scyl3 have been described. Studies have pointed to a role for SCYL1 and SCYL2 in regulating neuronal function and viability in mice and humans, but little is known about the biological function of SCYL3. Here, we show that the biochemical and cell biological properties of SCYL3 are similar to those of SCYL1 and both proteins work in conjunction to maintain motor neuron viability. Specifically, although lack of Scyl3 in mice has no apparent effect on embryogenesis and postnatal life, it accelerates the onset of the motor neuron disorder caused by Scyl1 deficiency. Growth abnormalities, motor dysfunction, hindlimb paralysis, muscle wasting, neurogenic atrophy, motor neuron degeneration, and loss of large-caliber axons in peripheral nerves occurred at an earlier age in Scyl1/Scyl3 double-deficient mice than in Scyl1-deficient mice. Disease onset also correlated with the mislocalization of TDP-43 in spinal motor neurons, suggesting that SCYL1 and SCYL3 regulate TDP-43 proteostasis. Together, our results demonstrate an overlapping role for SCYL1 and SCYL3 in vivo and highlight the importance the SCYL family of proteins in regulating neuronal function and survival. Only male mice were used in this study.SIGNIFICANCE STATEMENT SCYL1 and SCYL2, members of the SCY1-like family of pseudokinases, have well established roles in neuronal function. Herein, we uncover the role of SCYL3 in maintaining motor neuron viability. Although targeted disruption of Scyl3 in mice had little or no effect on embryonic development and postnatal life, it accelerated disease onset associated with the loss of Scyl1, a novel motor neuron disease gene in humans. Scyl1 and Scyl3 double-deficient mice had neuronal defects characteristic of amyotrophic lateral sclerosis, including TDP-43 pathology, at an earlier age than did Scyl1-deficient mice. Thus, we show that SCYL1 and SCYL3 play overlapping roles in maintaining motor neuronal viability in vivo and confirm that SCYL family members are critical regulators of neuronal function and survival.