Cytosolic domain of SIDT2 carries an arginine-rich motif that binds to RNA/DNA and is important for the direct transport of nucleic acids into lysosomes.

RNautophagy and DNautophagy (RDA) are unconventional autophagic pathways where nucleic acids are directly transported through the lysosomal membrane, then degraded inside lysosomes. We have previously shown that bitopic protein LAMP2C and putative RNA transporter SIDT2, both lysosomal membrane proteins, mediate the direct transport of nucleic acids into lysosomes and that LAMP2C interacts with the nucleic acids and functions as a receptor during RDA. Because SIDT2-mediated RDA occurs in isolated lysosomes that lack LAMP2C, in this study, we tested the hypothesis that SIDT2 itself could also interact with the nucleic acids. Our results show that SIDT2 directly binds RNA and DNA through an arginine-rich motif (ARM) located within its main cytosolic domain, and disruption of this motif dramatically impairs SIDT2-mediated RNautophagic activity. We also found that SIDT2 interacts with exon 1 of HTT (huntingtin) transcript through the ARM in a CAG-dependent manner. Moreover, overexpression of SIDT2 promoted degradation of HTT mRNA and reduced the levels of polyglutamine-expanded HTT aggregates, hallmarks of Huntington disease. In addition, a comparative analysis of LAMP2C and SIDT2 functions at the cellular level revealed that the two proteins exert a synergistic effect on RNautophagic activity and that the ARMs which mediate the interactions of SIDT2 and LAMP2C with RNA are essential for the synergy. Together, our results point out the importance of nucleic acid-binding capacity of SIDT2 for its function in translocating nucleic acids through the lipid bilayer and suggests a potential application of RNautophagy activation to reduce the expression levels of disease-causing toxic proteins. Abbreviations: ACTB/ß-actin: actin beta; ARM: arginine-rich motif; CBB: Coomassie Brilliant Blue; CD: cytosolic domain; COX4I1/COX4: cytochrome c oxidase subunit 4I1; E. coli: Escherichia coli; EGFP: enhanced green fluorescent protein; EtBr: ethidium bromide; FITC: fluorescein isothiocyanate; GAPDH: glyceraldehyde-3-phosphate dehydrogenase; GOLGA2/GM130: golgin A2; GST: glutathione S-transferase; HRP: horseradish peroxidase; HSPA5/GRP78: heat shock protein family A (Hsp70) member 5; HTT: huntingtin; HTTex1: exon 1 of the HTT gene; LAMP2: lysosomal associated membrane protein 2; LMNA: lamin A/C; PAGE: polyacrylamide gel electrophoresis; PBS: phosphate-buffered saline; PEI: polyethyleneimine; polyQ: polyglutamine; qPCR: quantitative PCR; RAB5A: RAB5A, member RAS oncogene family; RDA: RNautophagy and DNautophagy; SCARB2/LIMP2: scavenger receptor class B member 2; SDS: sodium dodecyl sulfate; SID-1: systemic RNA interference deficient-1; SIDT2: SID1 transmembrane family member 2; WT: wild type.

Lysosomal targeting of SIDT2 via multiple YxxΦ motifs is required for SIDT2 function in the process of RNautophagy.

RNA degradation is an essential process for maintaining cellular homeostasis. Previously, we discovered a novel RNA degradation system, RNautophagy, during which direct import of RNA into lysosomes in an ATP-dependent manner followed by degradation takes place. The putative nucleic acid transporter SID-1 transmembrane family member 2 (SIDT2) predominantly localizes to lysosomes and mediates the translocation of RNA into lysosomes during RNautophagy. However, little is known about the mechanisms of sorting SIDT2 to lysosomes. Here, we show that three cytosolic YxxΦ motifs (in which x is any amino acid and Φ is an amino acid with a bulky hydrophobic side chain) are required for the lysosomal localization of SIDT2, and that SIDT2 interacts with adaptor protein complexes AP-1 and AP-2. We also find that localization to lysosomes by these three motifs is necessary for SIDT2 function in the process of RNautophagy, and that SIDT2 strikingly increases endogenous RNA degradation at the cellular level. To our knowledge, this is the first study to report an endogenous intracellular protein for which overexpression substantially increased intracellular RNA degradation. This study provides new insight into lysosomal targeting of proteins and intracellular RNA degradation, and further confirms the critical function of SIDT2 in RNautophagy.This article has an associated First Person interview with the first author of the paper.

SIDT2 mediates gymnosis, the uptake of naked single-stranded oligonucleotides into living cells.

Single-stranded oligonucleotides (ssOligos) are efficiently taken up by living cells without the use of transfection reagents. This phenomenon called 'gymnosis' enables the sequence-specific silencing of target genes in various types of cells. Several antisense ssOligos are used for the treatment of human diseases. However, the molecular mechanism underlying the uptake of naked ssOligos into cells remains to be elucidated. Here, we show that systemic RNA interference deficient-1 (SID-1) transmembrane family 2 (SIDT2), a mammalian ortholog of the Caenorhabditis elegans double-stranded RNA channel SID-1, mediates gymnosis. We show that the uptake of naked ssOligos into cells is significantly downregulated by knockdown of SIDT2. Furthermore, knockdown of SIDT2 inhibited the effect of antisense RNA mediated by gymnosis. Overexpression of SIDT2 enhanced the uptake of naked ssOligos into cells, while a single amino acid mutation in SIDT2 abolished this effect. Our findings highlight the mechanism of extra- and intracellular RNA transport and may contribute to the further development of nucleic acid-based therapies.

Lysosomal membrane protein SIDT2 mediates the direct uptake of DNA by lysosomes.

Lysosomes degrade macromolecules such as proteins and nucleic acids. We previously identified 2 novel types of autophagy, RNautophagy and DNautophagy, where lysosomes directly take up RNA and DNA, in an ATP-dependent manner, for degradation. We have also reported that SIDT2 (SID1 transmembrane family, member 2), an ortholog of the Caenorhabditis elegans putative RNA transporter SID-1 (systemic RNA interference defective-1), mediates RNA translocation during RNautophagy. In this addendum, we report that SIDT2 also mediates DNA translocation in the process of DNautophagy. These findings help elucidate the mechanisms underlying the direct uptake of nucleic acids by lysosomes and the physiological functions of DNautophagy.

Lysosomal putative RNA transporter SIDT2 mediates direct uptake of RNA by lysosomes.

Lysosomes are thought to be the major intracellular compartment for the degradation of macromolecules. We recently identified a novel type of autophagy, RNautophagy, where RNA is directly taken up by lysosomes in an ATP-dependent manner and degraded. However, the mechanism of RNA translocation across the lysosomal membrane and the physiological role of RNautophagy remain unclear. In the present study, we performed gain- and loss-of-function studies with isolated lysosomes, and found that SIDT2 (SID1 transmembrane family, member 2), an ortholog of the Caenorhabditis elegans putative RNA transporter SID-1 (systemic RNA interference deficient-1), mediates RNA translocation during RNautophagy. We also observed that SIDT2 is a transmembrane protein, which predominantly localizes to lysosomes. Strikingly, knockdown of Sidt2 inhibited up to ˜50% of total RNA degradation at the cellular level, independently of macroautophagy. Moreover, we showed that this impairment is mainly due to inhibition of lysosomal RNA degradation, strongly suggesting that RNautophagy plays a significant role in constitutive cellular RNA degradation. Our results provide a novel insight into the mechanisms of RNA metabolism, intracellular RNA transport, and atypical types of autophagy.

RNautophagy/DNautophagy possesses selectivity for RNA/DNA substrates.

Lysosomes can degrade various biological macromolecules, including nucleic acids, proteins and lipids. Recently, we identified novel nucleic acid-degradation systems termed RNautophagy/DNautophagy (abbreviated as RDA), in which RNA and DNA are directly taken up by lysosomes in an ATP-dependent manner and degraded. We also found that a lysosomal membrane protein, LAMP2C, the cytoplasmic region of which binds to RNA and DNA, functions, at least in part, as an RNA/DNA receptor in the process of RDA. However, it has been unclear whether RDA possesses selectivity for RNA/DNA substrates and the RNA/DNA sequences that are recognized by LAMP2C have not been determined. In the present study, we found that the cytosolic region of LAMP2C binds to poly-G/dG, but not to poly-A/dA, poly-C/dC, poly-dT or poly-U. Consistent with this binding activity, poly-G/dG was transported into isolated lysosomes via RDA, while poly-A/dA, poly-C/dC, poly-dT and poly-U were not. GGGGGG or d(GGGG) sequences are essential for the interaction between poly-G/dG and LAMP2C. In addition to poly-G/dG, G/dG-rich sequences, such as a repeated GGGGCC sequence, interacted with the cytosolic region of LAMP2C. Our findings indicate that RDA does possess selectivity for RNA/DNA substrates and that at least some consecutive G/dG sequence(s) can mediate RDA.

An RNautophagy/DNautophagy receptor, LAMP2C, possesses an arginine-rich motif that mediates RNA/DNA-binding.

Lysosomes are sites for the degradation of diverse cellular components. We recently discovered novel lysosomal systems we termed RNautophagy and DNautophagy. In these systems, RNA and DNA, respectively, are directly imported into lysosomes and degraded. A lysosomal membrane protein, LAMP2C was identified as a receptor for these pathways. The short C-terminal cytosolic tail of LAMP2C binds directly to both RNA and DNA. In this study, we examined the mechanisms underlying recognition of nucleic acids by the cytosolic sequence of LAMP2C. We found that the sequence possesses features of the arginine-rich motif, an RNA-recognition motif found in a wide range of RNA-binding proteins. Substitution of arginine residues in the LAMP2C cytosolic sequence completely abolished its binding capacity for nucleic acids. A scrambled form of the sequence showed affinity to RNA and DNA equivalent to that of the wild-type sequence, as is the case for other arginine-rich motifs. We also found that cytosolic sequences of other LAMP family proteins, LAMP1 and CD68/LAMP4, also possess arginine residues, and show affinity for nucleic acids. Our results provide further insight into the mechanisms underlying RNautophagy and DNautophagy, and may contribute to a better understanding of lysosome function.

H89 (N-[2-p-bromocinnamylamino-ethyl]-5-isoquinolinesulphonamide) induces autophagy independently of protein kinase A inhibition.

Autophagy is a degradation pathway for cytoplasmic proteins and organelles in eukaryotes. Although the mechanisms of autophagy regulation are not completely understood, the target of rapamycin (TOR) signaling pathway plays a major role in controlling the induction of autophagy. Cyclic adenosine monophosphate (cAMP)/cAMP-dependent protein kinase A (PKA) has also been shown to regulate autophagy in yeast and mammalian cells. In an effort to elucidate the role of the cAMP/PKA pathway in autophagy, we used the PKA inhibitor N-[2-p-bromocinnamylamino-ethyl]-5-isoquinolinesulphonamide (H89) to treat mammalian cells. Our data demonstrated that H89 induced autophagy at 10 µM, which is a commonly used concentration for PKA inhibition, but PKA inhibition was not involved in the induction of autophagy. The effects of cAMP on autophagy seemed to be dependent on the cell type and the culture conditions. In addition, we investigated which protein kinase was involved in H89-induced autophagy because several kinases other than PKA have been shown to be inhibited by 10 µM of H89. There was no protein kinase largely responsible for autophagy induction, although the inhibition of Akt, which is a downstream effector protein kinase of phosphatidylinositol-3-kinase, appeared to be partially associated. Furthermore, H89-induced autophagy was independent of TOR. H89 is a widely used PKA inhibitor, but PKA-independent effects have been reported. Therefore, it is suggested that autophagy induction is a nonspecific effect of H89, and H89-induced autophagy is independent of the cAMP-PKA and the TOR pathways.